Patent Publication Number: US-2019178057-A1

Title: Machines, systems, computer-implemented methods, and computer program products to test and certify oil and gas equipment

Description:
CROSS REFERENCING OF RELATED APPLICATIONS 
     This application is a continuation of U.S. patent application Ser. No. 15/893,009, filed Feb. 9, 2018, entitled “Machines, Systems, Computer-Implemented Methods, and Computer Program Products to Test and Certify Oil and Gas Equipment,” which is a continuation of U.S. patent application Ser. No. 15/201,045, filed Jul. 1, 2016, entitled “Machines, Systems, Computer-Implemented Methods, and Computer Program Products to Test and Certify Oil and Gas Equipment,” which is a continuation of U.S. patent application Ser. No. 13/099,307, filed May 2, 2011, entitled “Machines, Systems, Computer-Implemented Methods, and Computer Program Products to Test and Certify Oil and Gas Equipment,” which claims priority to and the benefit of U.S. Provisional Patent Application Ser. No. 61/330,248 filed Apr. 30, 2010, entitled “Machines, Systems, Computer-Implemented Methods, and Computer Program Products to Test and Certify Oil and Gas Equipment,” each of which are incorporated herein by reference in their entirety for all purposes. 
    
    
     FIELD OF THE INVENTION 
     The present invention relates to oil and gas production. In more particular aspects, the present invention relates to testing and certification of equipment used in oil and gas production. 
     BACKGROUND 
     The production of oil and gas requires specialized well equipment, such as pipes, valves, joints, and fittings that operate in extreme conditions, including, for example, high pressure, temperature, volatility, and corrosivity. Such conditions promote the rapid wear of well equipment and increase the potential for failure. Moreover, when well equipment does fail, the impact of the failure is typically catastrophic. For example, the failure of well equipment can result in massive explosions that hurt workers, destroy property, and halt operations for a significant time—potentially costing millions of dollars in liabilities, repairs, and lost revenue. 
     Well equipment particularly susceptible to catastrophic failure includes, for example, the equipment used in the process of hydraulic fracturing known as “fracing” or “fracking.” The process of fracing creates or extends fractures in subterranean rock formations by pumping fluid into the formation at high pressure. For example, fluid-driven fractures can be formed at the borehole in a drilling operation and then “grown” or extended into the rock formations. The injected fluid may contain “proppant” particles, such as grains of sand or ceramic, to lodge in the fractures thereby keeping them open. Fracing is used to improve the rate at which oil and gas can be produced from a reservoir, and fracing is especially useful for extracting oil and gas from formations having low porosity and permeability, such as shale rock and other formations deep below the earth&#39;s surface. The equipment used in hydraulic fracturing for oil and gas wells can include, for example, a slurry blender, high pressure/volume fracturing pumps, high pressure treating iron, and other pipes, joints, valves, and fittings, which are known as “frac iron” or, simply, “iron.” For example, frac iron can include swivel joints, pup joints, plug valves, check valves and relief valves. 
     To mitigate the likelihood and impact of their failure, frac iron must be periodically inspected and recertified according to certain specifications, which can be provided by, for example, a manufacturer or operator of the frac iron. Because of the likelihood and impact of failure, inspections can be performed as frequently as every 90 days. Inspections and recertifications typically require several different test procedures, which may include, for example, a visual check of bores, connections, seal surfaces; wall thickness measurements to check for erosion or corrosion, for example, using ultrasonic measurement; crack tests, for example, using magnetic particle measurement; and pressure tests, for example, of over 20,000 pounds per square inch (PSI). 
     Previously known methods to certify frac iron were lengthy and laborious, often lasting one to three weeks and requiring a human tester to control all testing, to record the results manually, and later to enter the results into a database—costing valuable production capacity due to downtime. 
     Also, previously known methods to certify frac iron were susceptible to inconsistencies due to the manually intensive nature of the certification, such as inconsistent performance of testing operations and inconsistent adherence to prescribed test specifications. Also, for example, certification records were created by manual input, introducing human error and recording and measurement variances into the certification records. 
     Also, previously known methods to certify frac iron were susceptible to operational inefficiencies. For example, certification records were kept in hard copy, which did not allow on-site operators to readily access certifications while in the field, which may be a remote location such as an offshore rig. Furthermore, certification records and the test results associated therewith could not be tracked, updated, or reported on from a central control center. 
     SUMMARY OF THE INVENTION 
     Embodiments of the present invention provide systems, methods, and machines for testing and certifying well equipment that enhance testing management, certification management, field operations management, and asset management. For example, embodiments of the present invention increase efficiency in testing and certifying well equipment by providing a systematic solution to control testing operations. Also, embodiments of the present invention increase efficiency in testing and certifying well equipment by seamlessly generating, storing, and processing testing data immediately upon performance of the testing operations, allowing a user to view the testing data in real time. Also, embodiments of the present invention increase efficiency in testing and certifying well equipment by dynamically generating certificates and reports responsive to the testing data according to multiple formats or user criteria. 
     Furthermore, well equipment testing according to embodiments of the present invention benefit from an increased likelihood of effective and safe operation because embodiments of the present invention systematically ensuring that testers use the proper test specifications and perform all test operations according to defined test sequences. Also, well equipment tested according to embodiments of the present invention benefit from an increased likelihood of effective and safe operation because embodiments of the present invention systematically ensure that equipment that fail any test sequence according to defined testing specifications are scrapped in the system and are unable to proceed in further testing or operation. Also, well equipment testing according to embodiments of the present invention benefit from an increased likelihood of effective and safe operation because operational crews can more, readily access certificates, including comprehensive testing and certification data, on-demand and on-site. Furthermore, manufacturers and suppliers of well equipment can benefit from embodiments of the present invention by enhancing research and development efforts with greater knowledge of real-world wear patterns and wear rates for well equipment devices. 
     In view of the foregoing, applicant has provided a machine to manage periodic testing and certification of well equipment devices, the testing and certification being facilitated by a plurality of testing apparatus performing one or more testing operations upon the well equipment devices. The machine comprises a processor, a non-transitory memory, an input/output unit to communicate with the plurality of testing apparatus, a database positioned to match a device identifier to a well equipment device, a test specification, and a plurality of testing sequences. The machine also comprises a testing module stored in the memory, the memory being a tangible, non-transitory, computer-readable storage medium, and the testing module being operable by the processor, the testing module comprising a set of instructions that, when executed by the processor, cause the testing module to perform operations. The operations of the testing module include identifying a selected well equipment device, a device test specification, and a plurality of testing sequences, the identifying operation responsive to receiving a device identifier for the selected well equipment device, each testing sequence of the plurality of testing sequences to be performed by a corresponding testing apparatus of the plurality of testing apparatus, each testing sequence defining a sequence of testing operations. 
     The operations of the testing module further include selecting a testing sequence of the plurality of testing sequences, the selecting operation responsive to the selected well equipment device being positioned so that the corresponding testing apparatus for the selected testing sequence can perform testing operations upon the selected well equipment device. 
     The operations of the testing module further include controlling the corresponding testing apparatus for the selected testing sequence so that the corresponding testing apparatus performs the sequence of testing operations upon the selected well equipment device, the sequence of testing operations being performed responsive to the device test specification. The operations of the testing module further include generating testing data for the selected testing sequence responsive to receiving output from the corresponding testing apparatus for selected testing sequence performing the sequence of testing operations. 
     The operations of the testing module further include linking the testing data for the selected testing sequence to the device identifier for the selected well equipment device in the database so that a certificate can be generated responsive thereto; and    
     The machine also comprises a certification module stored in the memory, the memory being a tangible, non-transitory, computer-readable storage medium, and the certification module being operable by the processor, the certification module comprising a set of instructions that, when executed by the processor, cause the certification module to perform certain operations. 
     The operations of the certification module include identifying a selected well equipment device, a device test specification, and testing data for a plurality of testing sequences, the identifying operation responsive to receiving a device identifier for the selected well equipment device. 
     The operations of the certification module further include generating a certificate for the selected well equipment device responsive to the testing data for the plurality of testing sequences, the plurality of testing sequences having been performed upon the selected well equipment device responsive to the device test specification. 
     The operations of the certification module further include linking the certificate for the selected well equipment device to the device identifier for the selected well equipment device in the database so that the certificate can be readily recalled from the database responsive to the device identifier. 
     Also in view of the foregoing, applicant has provided a system to certify oil and gas well equipment. The system comprises a plurality of devices to be used in well equipment to define a plurality of well equipment devices, each well equipment device of the plurality of well equipment devices having a device identifier associated therewith. The system further comprises a central management server positioned to identify a device test specification and a plurality of testing sequences for a selected well equipment device responsive to receiving a device identifier for the selected well equipment device, the device test specification and the plurality of testing sequences defining certification criteria for the well equipment device. The system further comprises a plurality of testing apparatus, each testing apparatus positioned to perform a testing sequence upon the well equipment device, the testing sequence being a sequence of testing operations, the sequence of testing operations being performed responsive to the device test specification. The system further comprises a plurality of controllers, each controller positioned to receive commands responsive to the certification criteria from the central management server and to control the plurality of testing apparatus performing the sequence of testing operations upon the selected well equipment device responsive to the device test specification. The system further comprises a certificate generated responsive to the plurality of testing apparatus performing the plurality of testing sequences upon the well equipment device, the certificate indicating whether selected well equipment device has been tested according to the certification criteria within a pre-selected period of time. 
     Also in view of the foregoing, applicant has also provided a computer-implemented method to manage periodic testing of a plurality of well equipment devices, the testing being facilitated by a plurality of testing apparatus performing one or more testing operations upon the plurality of well equipment devices. The computer-implemented method comprises receiving a device identifier for a selected well equipment device of the plurality of well equipment devices. The computer-implemented method further comprises identifying the selected well equipment device, a device test specification, and plurality of testing sequences, the identifying operation being responsive to the receiving operation, each testing sequence of the plurality of testing sequences to be performed by a corresponding testing apparatus of the plurality of testing apparatus, each testing sequence defining a sequence of testing operations. The computer-implemented method further comprises selecting a testing sequence of the plurality of testing sequences to define a selected testing sequence, the selecting operation responsive to the selected well equipment device being positioned so that the corresponding testing apparatus for the selected testing sequence can perform testing operations upon the selected well equipment device. The computer-implemented method further comprises calibrating the corresponding testing apparatus for the selected testing sequence responsive to the device test specification. The computer-implemented method further comprises controlling the corresponding testing apparatus for the selected testing sequence so that the corresponding testing apparatus performs the sequence of testing operations upon the selected well equipment device, the sequence of testing operations being performed responsive to the device test specification. The computer-implemented method further comprises generating testing data for the selected testing sequence responsive to receiving output from the corresponding testing apparatus for selected testing sequence performing the sequence of testing operations. The computer-implemented method further comprises linking the testing data for the selected testing sequence to the device identifier for the selected well equipment device in a database so that a certificate can be generated responsive thereto. 
     Also in view of the foregoing, applicant has also provided a computer program product to manage periodic testing of a plurality of well equipment devices. The computer program product can be stored in a memory, the memory being a tangible, non-transitory, computer-readable storage medium, and the computer program product being operable by a processor. The computer program product comprises a set of instructions that, when executed by the processor, cause the testing module to perform certain operations. The operations performed by the computer program product includes identifying a selected well equipment device, a device test specification, and a plurality of testing sequences, the identifying operation responsive to receiving a device identifier for the selected well equipment device, each testing sequence of the plurality of testing sequences to be performed by a corresponding testing apparatus of the plurality of testing apparatus, each testing sequence defining a sequence of testing operations. The operations performed by the computer program product further includes selecting a testing sequence of the plurality of testing sequences, the selecting operation responsive to the selected well equipment device being positioned so that the corresponding testing apparatus for the selected testing sequence can perform testing operations upon the selected well equipment device. The operations performed by the computer program product further includes controlling the corresponding testing apparatus for the selected testing sequence so that the corresponding testing apparatus performs the sequence of testing operations upon the selected well equipment device, the sequence of testing operations being performed responsive to the device test specification. The operations performed by the computer program product further includes generating testing data for the selected testing sequence responsive to receiving output from the corresponding testing apparatus for selected testing sequence performing the sequence of testing operations. The operations performed by the computer program product further includes linking the testing data for the selected testing sequence to the device identifier for the selected well equipment device in the database so that a certificate can be generated responsive thereto. The operations performed by the computer program product further includes identifying a selected well equipment device, a device test specification, and testing data for a plurality of testing sequences, the identifying operation responsive to receiving a device identifier for the selected well equipment device. The operations performed by the computer program product further includes generating a certificate for the selected well equipment device responsive to the testing data for the plurality of testing sequences, the plurality of testing sequences having been performed upon the selected well equipment device responsive to the device test specification. The operations performed by the computer program product further includes linking the certificate for the selected well equipment device to the device identifier for the selected well equipment device in the database so that the certificate can be readily recalled from the database responsive to the device identifier. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       So that the manner in which the features and benefits of the invention, as well as others which will become apparent, may be understood in more detail, a more particular description of the invention briefly summarized above may be had by reference to the embodiments thereof which are illustrated in the appended drawings, which form a part of this specification. It is also to be noted, however, that the drawings illustrate only various embodiments of the invention and are therefore not to be considered limiting of the invention&#39;s scope as it may include other effective embodiments as well. 
         FIG. 1  is a schematic diagram illustrating exemplary data flows and interactions among components of a system to certify well equipment according to an embodiment of the present invention; 
         FIG. 2  is a schematic illustrating exemplary components and connections of a central management server to certify well equipment according to an embodiment of the present invention; 
         FIG. 3A  is a flowchart illustrating a first portion of program product logic and computer-implemented methods for certifying well equipment according to an embodiment of the present invention; 
         FIG. 3B  is a flowchart illustrating a second portion of the program product logic and computer-implemented methods for certifying well equipment according to an embodiment of the present invention; 
         FIG. 4  is a database diagram illustrating exemplary data structures according to an embodiment of the present invention; 
         FIG. 5  is an exemplary certificate according to an embodiment of the present invention; 
         FIG. 6A  is a flowchart illustrating a first portion of a first process flow according to embodiments of the present invention; 
         FIG. 6B  is a flowchart illustrating a second portion of the first process flow according to embodiments of the present invention; 
         FIG. 7A  is a flowchart illustrating a first portion of a second process flow according to embodiments of the present invention; 
         FIG. 7B  is a flowchart illustrating a second portion of the second process flow according to embodiments of the present invention; 
         FIG. 8A  is a flowchart illustrating a first portion of a third process flow according to embodiments of the present invention; 
         FIG. 8B  is a flowchart illustrating a second portion of the third process flow according to embodiments of the present invention; 
         FIG. 9  is a first testing interface display according to embodiments of the present invention; 
         FIG. 10  is a second testing interface display according to embodiments of the present invention; 
         FIG. 11  is a third testing interface display according to embodiments of the present invention; 
         FIG. 12  is a fourth testing interface display according to embodiments of the present invention; 
         FIG. 13  is a fifth testing interface display according to embodiments of the present invention; 
         FIG. 14  is a sixth testing interface display according to embodiments of the present invention; 
         FIG. 15A  is a seventh testing interface display according to embodiments of the present invention; 
         FIG. 15B  is a variation of the seventh testing interface display according to embodiments of the present invention; 
         FIG. 16  is a eighth testing interface display according to embodiments of the present invention; 
         FIG. 17  is a ninth testing interface display according to embodiments of the present invention; 
         FIG. 18  is a tenth testing interface display according to embodiments of the present invention; 
         FIG. 19  is a eleventh testing interface display according to embodiments of the present invention; 
         FIG. 20  is a twelfth testing interface display according to embodiments of the present invention; 
         FIG. 21  is a thirteenth testing interface display according to embodiments of the present invention; 
         FIG. 22  is a fourteenth testing interface display according to embodiments of the present invention; 
         FIG. 23  is a fifteenth testing interface display according to embodiments of the present invention; 
         FIG. 24  is a first reporting interface display according to embodiments of the present invention; and 
         FIG. 25  is a second reporting interface display according to embodiments of the present invention. 
     
    
    
     DETAILED DESCRIPTION 
     The present invention will now be described more fully hereinafter with reference to the accompanying drawings, which illustrate various embodiments of the invention. This invention, however, may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. It is to be fully recognized that the different teachings of the various embodiments discussed below may be employed separately or in any suitable combination to produce desired results. The various characteristics mentioned above, as well as other features and characteristics described in more detail below, will be readily apparent to those skilled in the art upon reading the following detailed description of the various embodiments, and by referring to the accompanying drawings. In the drawings and description that follow, like parts are marked throughout the specification and drawings with the same reference numerals, respectively. The prime notation, if used, indicates similar elements in alternative embodiments. The drawings are not necessarily to scale. Certain features of the disclosure may be shown exaggerated in scale or in somewhat schematic form and some details of conventional elements may not be shown in the interest of clarity and conciseness. 
     Accordingly, embodiments of the present invention improve safety, effectiveness, and efficiency of operating well equipment by meeting the foregoing objectives to mitigate the likelihood and impact of the failure of such equipment. In embodiments of the present invention, “well equipment devices” includes the equipment and devices used in hydraulic fracturing for oil and gas wells, i.e. “high pressure hydraulic fracturing flow iron,” “frac iron,” or, simply, “iron.” Frac iron can include, for example, a slurry blender, high pressure/volume fracturing pumps, high pressure treating iron, and other pipes, joints, valves, and fittings. For example, frac iron can include swivel joints, pup joints, plug valves, check valves and relief valves. Furthermore, by way of example, frac iron can include any type of ball injector, crow&#39;s foot, air chamber, crossover, hose, pipes/piping, hose loop, ball injector tee body, tee, wye, lateral, ell, check valve, plug valve, wellhead adapter, swivel joint, plug, relief valve, densometer, cross, frac pump, or cement pump. Those skilled in the art will appreciate that embodiments of the present invention are not limited to uses related to in oil and gas wells, but, rather, embodiments of the present invention are applicable to processes for testing or certifying any industrial equipment or device, and at any stage in the lifespan of the equipment, including during or after manufacturing and before, during, or after use or ongoing operations. 
       FIG. 1  illustrates a central management server  100  for performing operations of a testing module  220  and a certification module  210 . The central management server  100  is positioned to be in communication with a plurality of testing apparatus  110 . The plurality of testing apparatus  110  is capable of performing testing operations on a selected well equipment device  101 . The central management server  100  is positioned to systematically control the performing of testing operations upon the well equipment device  101 , systematically record and process the results of such testing operations, and systematically generate a certificate responsive to such recording and processing. Embodiments of the present invention providing systems, methods, and machines to certify of well equipment and are further described herein with specific reference to the drawings. 
     Central Management Server  100   
     An embodiment of a central management server  100 , as illustrated in  FIG. 2 , can be configured as a computer, a server, or a machine of distributed computers or servers that at least include non-transitory memory  240 , program products  210 ,  220 , and  230 , a processor or processors  251 , an input/output device or devices (“I/O”)  252 . 
     I/O  252  connects the central management server  100  to a database  170 , a testing interface  150 , and one or more testing apparatus  110  (although represented as one block, those of skill in the art will appreciate that a plurality of testing apparatus  110  may include one or more links to the I/O) to thereby allow central management server  100  to send and receive commands and data, I/O  252  can be any I/O including, but not limited to a network card/controller connected by a PCI (Peripheral Component Interconnect) bus to the motherboard, or hardware built into the motherboard of the central management server  100  to connect same to the forgoing database, interface, and apparatus. 
     As those of skill in the art will appreciate, I/O  252  can connect the central management server  100  with any other compatible machine, server, system, device, or equipment having a suitable physical interface and that I/O  252  and/or computer program products  210 ,  220 , and  230  on non-transitory memory  240  may be positioned to understand, convert, or translate application or communication protocols of such machines, servers, systems, devices, or equipment irrespective of native protocols. Also, one of skill in the art will understand that I/O  252  can include or otherwise incorporate any logical or physical technology necessary to effect a connection with any of the aforementioned devices, including, for example, hubs, switches, routers, converters, amplifiers, and wireless transceivers. For example, as is further described herein, I/O  252  can also connect the central management server  100  to devices for interacting with radio frequency identification (RFID) devices, such as an RFID reader or interrogator  130  and an RFID writer  140 . The central management server  100  can further connect to a remote user interface  160  for interacting with a remote user  161 , as is also discussed further herein. Also, the plurality of testing apparatus  110 , RFID reader  130 , and the RFID writer  140  may be configured as peripherals to the testing interface  150 . Also, there a testing apparatus  110  interface  253 , such as a programmable logic controller (PLC), an interface between the I/O  252  and the plurality of testing apparatus  110  to control the plurality of testing apparatus  110 . 
     As can be seen in  FIG. 2 , the I/O  252  is connected to a processor  251 . The processor  251  is the “brains” of the central management server, and as such executes program products  210 ,  220 , and  230  and works in conjunction with the I/O  252  to direct data to the non-transitory memory  240  and to send data from the non-transitory memory  240  to the database  170 , the testing interface  150 , and one or more testing apparatus  110 . The processor  251  can be any commercially available processor, or plurality of processors, adapted for use in or with the central management server  100 , e.g., Intel® Xeon® multicore processors, Intel® micro-architecture Nehalem, and AMD Opteron™ multicore processors. As one skilled in the art will appreciate, processor  251  may also include components that allow the central management server  100  to be connected to a display, as will be understood by those skilled in the art, and keyboard or other peripherals that would allow a user to directly or indirectly access the processor  251  and non-transitory memory  240 . 
     Non-transitory memory  240  stores computer program products  210 ,  220 , and  230  having instructions for execution on the processor  251 , and consists of both non-volatile memory, e.g., hard disks, flash memory, optical disks, and the like, and volatile memory, e.g., SRAM, DRAM, and SDRAM as required to support embodiments of the instant invention. As one skilled in the art will appreciate, though the non-transitory memory  240  is depicted on, e.g., a motherboard, of the central management server  100 , the non-transitory memory  240  may also be a separate component or device, e.g., FLASH memory, connected to the central management server  100  through the I/O  252 . The non-transitory memory  240  may also store applications that various workstations or remote units can access and run on the central management server  100 . For example, a testing user  151  may access applications and computer program products stored on the non-transitory memory  240  and run on the processor  251  using the testing interface  150 . Importantly, non-transitory memory  240  stores the program products  210 ,  220 , and  230  of the instant invention. As one skilled in the art will understand, the program products  210 ,  220 , and  230 , along with one or more databases/tables/fields/records for data associated with the selected well equipment device  101  can be stored either in non-transitory memory  240  or in separate non-transitory memory associated, for example, with a storage medium such as database  170 , positioned in communication with the central management server  100 . 
     Database  170   
     As seen in  FIG. 1  and  FIG. 2 , the database  170  is in communication with the central management server  100 . Although the database  170  is illustrated according to an embodiment in which the database  170  is separate and distinct from the central management server  100 , for example, as a database server, the present invention may also include any arrangement of the database  170  in communication with the central management server  100 , including the database  170  being incorporated into the same computer, server, machine, or system constituting the central management server  100 , as one physical unit, for example, as an application or partition in the central management server  100  or as an installed component of the central management server  100  communicating with the processor  251  through the use of the I/O and having, for example, a database memory separate and distinct from memory  240 , such as a hard drive, optical storage, or the like. Database  170 , as is understood in the art, can include a processor directing data from a bus into the database memory, which can be, for example, a hard drive, optical storage or the like, and computer software that provides computers, including the central management server, access the data therein. 
     The database  170  can store therein a data structure or data structures relating to the well equipment devices  101  to be tested and all data generated during the execution of the testing module  211  and certification module  210 , as is further discussed herein. In embodiments, database  170  is a relational database positioned to match data by using common data found between data sets, the data sets being organized according to tables  400 ,  410 ,  420 ,  430 ,  440 , and  450  as seen in  FIG. 4 . As will be understood by those skilled in the art,  FIG. 4  illustrates an exemplary set of data structures only, and there may be other unique table structures positioned to relate and match the data in manners commensurate with the embodiments of the present invention. Data stored in the database  170  may be updated as needed, for example, by a user with administrative access to the database to add new well equipment devices to the database as they become supported. As is described further herein with relation to the computer program products, database  170  can be positioned to store data in tables relating to the unique device tested  400 , parts in a parts library  410 , test specifications in a test specification library  420 , test sequences in a test sequence library  430 , test data in a test data repository  440 , and certificate data in a certificate data repository  450 . And as is described further herein, the database  170  is positioned to match common data appearing in the foregoing tables. 
     Testing Apparatus  110   
     As shown in  FIG. 1  and  FIG. 2 , the plurality of testing apparatus  110  are in communication with the central management server  100 . The plurality of testing apparatus  110  perform testing operations under the control of the central management server  110  and provide tools or devices to gather testing data  440  as shown in  FIG. 4 , i.e., the data that serves as the basis for the certification. In embodiments, the plurality of testing apparatus  110  at least includes an ultrasonic wall thickness meter (“UT meter”) and a pressure test pump having a transducer. The plurality of testing apparatus  110  can include any other device or unit capable of being employed either manually or under automated control by the central management server  100  to interact with the well equipment device  101 . Other testing apparatus  110  can include, for example, digital calipers. A local user may employ embodiments of the present invention, for example, by positioning the frac iron to be tested  101  in a testing station adapted for the test performed, and by manually configuring the frac iron  101  to safely and effectively interact with the testing apparatus  110  for the intended test. 
     Although shown as separate blocks in  FIG. 1 , the testing interface  150 , which can be a personal computer (PC), can be connected to a peripheral testing apparatus  110  to control or collect data from a testing apparatus  110  connected as a peripheral to an input/output unit of the PC. The combination of the testing apparatus  110  and a PC may be referred to, collectively, as a testing apparatus  110 . PC or testing interface  150  can connect to a peripheral testing apparatus  110  via any connection type known to those in the art, such as a Universal Serial Bus connection (USB), and such connection may include analog inputs and digital inputs, wired and wireless, and including analog-to-digital converters and amplifiers for digital inputs. 
     The plurality of testing apparatus  110  and a PC incorporated with a peripheral testing apparatus  110  can be a mobile unit or units having remote or wireless connectivity to central management server  100  using any protocols or standards known in the art, including Wi-Fi, GSM, and WIMAX, for example. Mobile units may also be synchronized with central management server through periodic wired or wireless connections when returning from field use. The PC can be, for example, any suitable PC known in the art and is preferably a Panasonic® Toughbook® or other portable, notebook, laptop, or tablet computer preferably designed to withstand vibration, drops, spills, extreme temperature, and other rough handling and conditions common to industrial use. 
     The UT meter can be, for example, an Olympus® MG2DL, or any similar UT meter known in the art. The UT meter can include, for example, features such as B-scan, gain adjust, auto sensitivity optimizations, echo-to-echo, differential mode, hi-low alarm, and live A-scan. The UT meter can also include a file-based alphanumeric data logger and an interface program for transferring data bi-directionally to and from a PC. The testing apparatus  110  can include a PC, such as described above, for enabling data and control functions of a peripheral testing apparatus  110  such as a UT meter. 
     The pressure test pump and transducer can be any suitable pressure test pump known in the art. Preferably, embodiments of the invention employ an X45 series model 345 Viatran® test and control pressure sensor, which can, for example, operate in the range of 0-100,000 psi with output in the range of 4-20 mA. As is known in the art, the testing apparatus  110  can include a control interface such as a programmable logic controller (PLC) for communication with and control of the pressure test pump and transducer. 
     Testing User  151  and Testing Interface  150   
     As described above, a testing user  151  may employ embodiments of the present invention, for example, by positioning the frac iron to be tested  101  in a testing station adapted for the test to be performed, and will manually configure the frac iron  101  to safely and effectively interact with the testing apparatus  110  for the intended test. In other embodiments, the testing user may perform testing operations according to instructions provided by the central management server  110  and displayed, for example, on the testing interface  150 . The testing user  151  may provide the means of manually gathering testing data  440  as shown in  FIG. 4 , i.e., the data that serves as the basis for the certification. Testing operations, as described above with reference to the testing apparatus  110 , may be systematic, manual, or hybrid systematic/manual. For example, a sequence of testing operations for testing wall thickness of the frac iron may include systematic test operations to be performed by a testing apparatus  110 , such as a UT meter, and manual operations to be performed by a testing user  151 , such as using digital calipers to measure wall thickness or other dimensions of the frac iron, as can be seen in  FIGS. 15-16 , for example. Likewise, other sequences of testing operations may be fully manual, such as the mag particle test discussed further herein. 
     Also as described above, the testing interface  150  may be a PC, which may be any desktop, laptop, notebook, tablet, or portable computer known to those in the art. As is known the art, the testing interface  150  can include any number of peripheral devices to interact with the testing user  151 , including a keyboard, mouse, control stick/joystick, and memory reader for receiving data input and a display screen, printer, and local storage device for outputting or storing data. Furthermore, embodiments of invention have a testing interface with a touch-sensitive screen (e.g., using a stylus) for interactive display/input so that users can select parts responsive to viewing them on the display of the testing interface  150  and thereafter performing testing operations responsive to the selection, in communication with the testing module  210 . The testing interface  150  may connect with the central management server  100  via any communications interface known to those of skill in the art, wired or wireless, and is preferably a secure local Intranet or other authenticated and encrypted communications network, including a VPN over the Internet. 
     Certificate  500   
       FIG. 5  sets forth an exemplary certificate  500  generated responsive to embodiments of the present invention. The certificate  500  relates to data stored in the database  170 , for example, the certificate data  450  as shown in  FIG. 4 . The certificate  500 , as is appreciated by those skilled in the art, can be a paper document printout or an electronic document in a format such as Adobe® Portable Document Format (.PDF), Microsoft® Word (.DOC or .DOCX), or a similar format. The certificate  500 , for example, can be a paper document printout, as it is the custom in drilling and fracing operations for a paper document printout of a certificate to be presented to company personnel when well equipment is brought on-site in field operations. The company personnel takes possession of the physical document and reviews the testing parameters and testing results documented thereon to verify the quality of the equipment brought on site. 
     The certificate  500  can reference the well equipment device  101  by a unique device identifier, such as the serial number  501 , which can relate to data stored in database  170  in the device information table  400 . The certificate  500  can contain a summary indication as to whether certain test sequences were graded as a “PASS” or a “FAIL”  502 . The grading operation, for example, can be performed by a certification module  220  computer program product operating on the central management server  100 . The PASS or FAIL grading  502  can relate to data stored in the database  170 , for example, the certificate data  450  and the testing data  440  shown in  FIG. 4 . The certificate  500  can also contain a summary or other rendering of testing data responsive to testing operations being performed on the well equipment device  101 , for example, a graphical representation of a pressure test  503 . Graphical representation  503  can relate to data stored in the database  170  in the certificate data table  450  and the testing data table  440 . 
     The certificate  500  can also contain a summary indication as to measured qualities of the selected well equipment device  101  and their relation to the qualities demanded by the test specification. For example, measured wall thickness value  505  appears adjacent to demanded wall thickness value  506 . Additionally, drawing  504  shows a graphical representation of the parameters measured according to the test specification, as referenced by letter key (e.g., “A,” “B,” and “C”). 
     In certain embodiments of the present invention, a certificate can be stored in a proprietary data table format so that a lightweight electronic copy of the certificate, and an “RFID certificate” can be stored directly onto RFID tag  135  attached to the selected well equipment  101 . For example, as understood by those skilled in the art, the RFID certificate can be written to an RFID tag  135  attached to the well equipment so that the certificate can be readily accessed in the field using an RFID reader device  130  capable of recognizing the proprietary data table format. The RFID certificate can include all fields available on the paper certificate  500 , including device identifier  501 , pass or fail grading  502 , tabular summary or rendering of test data  503 , drawing  504 , measured values  505 , and demanded values  506 . The tabular summary or rendering  503  and the drawing  504  can be encoded, for example, using lightweight vector-based primitive formats. Also, RFID certificate will allow new schemes for protecting certificate data heretofore unavailable for field use, for example, by having individual cells in the table that are protected according to user access schemes such as read-only, read-write, or no access. For example, the serial number and the certification may be read-only to all; the certificate data may be read-only to many and read-write to few; and custom fields may be user-configurable. 
     Testing Module  210   
     As is shown in  FIG. 2 , the testing module  210  may be a computer program product stored in the memory  240  on the central management server  100  and operable on the processor  251  thereof. Computer program product  210  contains instructions that are operable on the processor  251  that cause the testing module  210  and the central management server  100  to perform the operations discussed further herein. 
     The testing module  210  can interact with the processor to receive or transmit data, instructions, and other information from or to any of the devices connected to I/O  252 . In embodiments discussed below, the testing module  210  at least interacts with the testing interface  150 , testing apparatus  110 , RFID reader  130 , and database  170 . Although testing interface  150  has been described to be a personal computer (PC), testing interface  150  can also be implemented in whole or in part as a user terminal interface on the central management server  100  itself, or using a keyboard, display, or media inputs and outputs connecting to the I/O  252 . Testing interface  150  can also be a lightweight graphical user interface (GUI) operable over a web browser and viewable on any browser-enabled device, such as a PC, smart phone, or other equipment having a processor and computer functionality. Testing interface  150 , for example, can receive user-selected identifiers or other user-selected values or parameters from a testing user as will be described in further detail below and can display identifiers, values, parameters, and other specification data, for example, as can be shown with reference to the selection, input, or display fields  900 ,  1000 ,  1100 - 1101 , and  1200 - 1205  in  FIGS. 9-12 . Other user selection, input, or display fields are also shown elsewhere in  FIGS. 13-25 , as will be apparent to those having skill in the art. 
     The testing module  210  can receive a device identifier for a selected well equipment device  101 , the selected well equipment device being a well equipment device positioned to undergo testing and certification, i.e., in the testing warehouse, on a testing trailer, or otherwise positioned at a testing station. In the embodiment of the present invention, only one well equipment device is tested at any given time using any particular testing apparatus  110 . It is possible, however, that multiple instances or threads of the testing module  210  can run on the processor  251  concurrently, with each instance being directed to the testing of a different piece of well equipment positioned for testing. It is also possible that multiple testing apparatus  110  of the same type may be employed to perform the same test sequence in simultaneous testing operations performed on multiple well equipment devices  101 . 
     The testing module  210  can receive a serial number as a device identifier as shown in  FIG. 6A . The testing module  210  can receive a serial number as a device identifier, for example, by receiving input from the testing interface  150  as entered therein by a testing user  151 . The testing module  210  can also receive a device identifier, such as a serial number, from a peripheral device, such as an RFID reader  130 , as is discussed further herein. 
     The testing module  210  can identify the selected well equipment device responsive to the device identifier as shown in and match the selected well equipment to: (i) device library information as shown in  FIG. 4  at table  400 , the device library information including a part number, and (ii) a part library information at table  410  including type, test specification, and test profile. If the testing module  210  is unable to identify the foregoing information (i.e., the device has not yet been tested), then the testing module  210  can prompt the testing user  151  to enter information to identify the device as shown in  FIG. 9 . Once the testing module  210  has matched the device  101  to a part number, the testing module  210  can match the device to a test specification and a test profile as shown in  FIG. 4  at tables  420  and  430 . The test specification can be criteria to which the testing operations will be performed, for example, as specified by the manufacturer or the customer. Test specifications can include, for example, a series of benchmark parameters as shown in  FIG. 5  at  506 . Test specifications can also include, for example, a schematic associated with the series of parameters as shown in  FIG. 5  at  504 . 
     The test profile as shown in  FIG. 4  at table  430  may be a plurality of test sequences that are to be performed upon the well equipment device. A test profile may indicate that certain test sequences shall be run on certain parts, but not on others. For example, test profiles may be defined by “levels” as set forth by the logical process flows shown in  FIGS. 6A-9 . 
     Level 1, as set forth in  FIG. 6A , can include, for example, making an inventory of all iron and entering al serial numbers or parts and specifications into the system. Then a testing user can visually examine and record any defects, damage, worn bodies, threads, and wing nuts on the iron. If the visual examine is acceptable, the tester can proceed with a wall thickness test, as discussed further herein. If the visual examination is unsuccessful, the user can scrap the iron in the database, mark the part with orange paint, and return or destroy the iron so that it becomes unusable. If the wall thickness is acceptable, the customer can be contacted if the wall thickness is within 5% of the minimum value set forth in the testing specification. If not, the testing user can proceed to the pressure test. If the pressure test is acceptable, the final inspection to be signed off by leading supervisor. If continued testing is desired, the tester can proceed to Level 2 before performing the pressure test. 
     Level 2, as set forth in  FIG. 7A , can include, for example, dismantling and stripping down and discarding all rubber seals and worn or corroded parts, then cleaning and removing grease from affected parts with solvent. Also, the testing user can perform a surface preparation in caustic solution tank, de-scale surfaces area to remove dirt scale, rust, and paint, and pressure rinse to remove caustic solution. The testing user then performs the visual examination as specified for Level 1, and may scrap the part also as specified for Level 1. If proceeding to Level 3 is acceptable, the testing user goes to Level 3 before performing the pressure test. Otherwise, the pressure test can be performed as specified for Level 1. 
     Level 3, as set forth in  FIG. 8A , can include, for example, inspecting the part to make sure its free from all oil, grease, paint, scale, rust, and all contaminates that might degrade the result of this inspection. The testing user then coats area to be inspected with wet fluorescent bath and puts a yoke on the part to create magnetic field. The user can pass the part for the magnetic particle test if, using a black light to check for indications of cracks and rechecking at right angles, the user finds no indications of cracks. If the magnetic particle test fails, the user can scrap the iron in the database as set forth for Level 1. After cleaning the part and completing the inspection buyoff, the testing user can reassemble and fit with news seals and any spare parts required. Thereafter the testing user can perform the pressure test as specified for Level 1 and proceed to paint per the customer&#39;s specifications or according to standardized paint schemes as set forth in  FIG. 8B . After painting, the supervising leader must sign off on the final inspection. 
     Test sequences  1300  can include, for example, visual inspection, wall thickness inspection, disassembly/assembly, magnetic (“mag”) particle inspection, pressure test, paint, and final inspection. As shown in  FIG. 13 , test sequences available for the device  101 , (i.e., available according to the test profile  430 ) can be displayed to the testing user  151  using the testing interface  150  so that the testing user  151  may select one of the available test sequences to be performed. 
     Test sequences as shown in  FIG. 13  may correspond to one of a plurality of testing apparatus  110 . For example, the test sequence “wall thickness inspection” corresponds to the UT meter testing apparatus  110  and the test sequence “pressure test” corresponds to the pressure test pump and transducer. Other test sequences shown in  FIG. 13  may correspond to manual procedures; for example, the test sequence “visual inspection” corresponds only to operations to be performed by the testing user  151 . Each test sequence, as shown in table  440  of  FIG. 4 , corresponds to a sequence of testing operations to be performed upon the well equipment device  101 . 
     Once the testing interface  150  displays the plurality of test sequences  440  available for the well equipment device, the testing user  151  can select a test sequence to be performed. The test sequence should correspond to the testing user positioning the selected well equipment device so that the testing apparatus  110  can perform the testing operations. For example, if the testing user  151  has selected the pressure test sequence, the testing user must also ensure that the appropriate testing apparatus  110  (e.g., the pressure pump and transducer) is positioned upon the selected well equipment device so that the test can be properly performed. 
     If the testing user  151  has selected the pressure test sequence or the wall thickness inspection sequence, the testing module  210  will calibrate the testing apparatus  110  as shown in  FIG. 14  and  FIGS. 15A and 15B . In certain embodiments, the calibration  1400 ,  1500  can be performed responsive to the tolerances as specified in the test specification  420 . Calibration can be performed, for example, by shoring a transducer of the testing apparatus  110  to return a rated pressure value or a baseline calibration setting by the manufacturer, as will be understood by those skilled in the art. Embodiments of the present invention can receive the baseline calibration setting returned and configure a calibration setting responsive thereto. 
     According to certain embodiments of the present invention, the testing module  210  systematically controls the performance of testing operations in certain test sequences. For such testing modules having full systematic control of performing the testing operations, e.g., the pressure test sequence, the testing user  151  can initiate the performance of the testing operations to be controlled by the central management server  100 , as shown at control deck  1600  in  FIG. 16 . The testing module  210  can control the corresponding testing apparatus  110  for the selected testing sequence so that the corresponding testing apparatus  110  performs the sequence of testing operations upon the selected well equipment device  101 . For example, the pressure test sequence can be performed responsive to the pressure criteria set forth in the test specification. As shown in  FIG. 17 , the pressure test proceeds systematically as shown in test chart  1700  and the test module controls the performance of a pressurization of the selected well equipment device  101  for a preselected period of time, for example, as specified in the test specification. 
     In further embodiments of the present invention, the testing module  210  systematically controls the performance of some testing operations and requires manual performance of other testing operations (“hybrid systematic/manual”). For testing modules having hybrid systematic/manual performance of testing operations, such as for wall thickness inspection, the testing user  151  can initiate the performance of the testing operations to be controlled by the central management server  100 , and the central management server  100  can control the testing apparatus  110  as discussed above with respect to fully systematic testing. Also, the testing module  210  can prompt the testing user  151  with instructions for the testing user  151  to perform testing operations pursuant to the test specification. As shown in  FIG. 18  and  FIG. 19 , the thickness at “Location A” can be measured and input  1800 ,  1900  either by the UT Meter or by the testing user  151  manually measuring Location A with a digital caliper. The testing module  210  transmits the schematic from the test specification to the testing interface  150  so that it may be displayed  1901  to the testing user  151  and instructs the testing user  151  how to perform the test operations with respect to the information set forth in the schematic and test specification. 
     In further embodiments of the present invention, the testing module  210  requires full manual performance of the testing operations for certain test sequences. For testing modules having full manual performance of testing operations, such as for the visual inspection sequence, the testing module  210  can prompt the testing user  151  with instructions for the testing user  151  to perform testing operations pursuant to the test specification. As shown in  FIGS. 20-21 , band information  2000  and paint parameters  2100  can be input by the testing user  151  responsive to instructions provided by the testing module  210  to the test interface  150 , the testing module  210  providing such instructions responsive to the sequence of testing operations and the test specification. As can be seen in  FIG. 17 , for example, the testing interface  150  can display the schematic  2001  from the test specification to the testing user  151  and instructs the user how to perform the test operations with respect to information set forth in the schematic and the test specification. 
     Responsive to systematic, manual, or hybrid systematic/manual performance of the test operation described above, the testing module  210  receives testing data either as captured by the testing apparatus  110  for the corresponding testing sequence or as captured by the testing user  151  and entered into the testing interface  150  according to specific instructions provided by the testing module  210 , e.g., at banding menu  2000 . As shown in  FIG. 4 , the testing data is stored in the table  440  and linked to the device library  400  for the selected well equipment device  101 . Also as shown in  FIG. 4 , an exemplary embodiment of the testing data in table  440  can have individual cells for each testing sequence (e.g., wall thickness, pressure test, visual inspection, etc.). The testing data in table  440  can be used, as is discussed further herein, to generate certification data by execution of the certification module  220  on the processor  251 . 
     Additionally, further embodiments of the present invention include certain test sequences as described in  FIGS. 6A-9 . These test sequences, for example, can include disassembly/assembly, magnetic particle (“mag particle”) inspection, paint, and final inspection. Although an embodiment of the invention includes manual performance of the test operations for these sequences, each of these test sequences may be implemented either by systematic, manual, or hybrid systematic/manual performance of the testing operations. Regardless of whether the performance of the testing operations are performed systematically or manually, those skilled in the art will realize that all testing operations are performed responsive to a command or instruction being systematically issued by the testing module  210  when executed on the central management server  100 . As such, any test operation described herein as manual can be performed systematically provided there exists a testing apparatus  110  that can receive an instruction from the central management server  100  to perform the operation. For example, the performance of test operations using a digital caliper may be performed either manually or systematically, although an embodiment employs manual performance of such operations. Those skilled in the art will understand that it is within the scope of the invention to employ a testing apparatus  110  having a digital caliper, actuator, and an control device to systematically perform a wall thickness measurement using a digital caliper in addition to the embodiment employing manual performance. Likewise, it will be understood by those in the art that any manual operation described herein may also be performed systematically under the architecture of the central management server as set forth in  FIG. 2 . 
     Certification Module  220   
     As is shown in  FIG. 2 , the certification module  220  may be a computer program product stored in the non-transitory memory  240  on the central management server  100  and operable on the processor  251  thereof. Computer program product  220  contains instructions that are operable on the processor  251  that cause the certification module  220  and the central management server  100  to perform the operations discussed further herein. 
     The certification module  220  can interact with the processor to receive or transmit data, instructions, and other information from or to any of the devices connected to I/O  252 . In addition both the certification module  220  and the testing module  210  are in communication with the processor  251  and the non-transitory memory  240  so that modules can pass or return variables between modules according to a shared API or access global variables being stored on the non-transitory memory  240  to ensure interoperability and open communication between computer program products in communication with the processor  251 . Likewise, those skilled in the art will understand that computer program products  220  and  210  are capable of passing, returning, or referencing common variables regardless of whether computer program products are executed on the same processor  251 , but that a common API will allow interoperability and open communications. In embodiments discussed below, the certification module  220  at least interacts with the testing interface  150 , RFID reader  130 , RFID writer  140 , and database  170 . Although testing interface  150  has been described to be a PC, testing interface  150  can also be implemented in whole or in part as a user terminal interface on the central management server  100  itself, using a keyboard, display, or media inputs and outputs connecting to the I/O  252 . The testing interface  150  can also be a lightweight graphical user interface (GUI) operable over a web browser and viewable on any browser-enabled device, such as a PC, smart phone, or other equipment having a processor and computer functionality. 
     The certification module  220  can receive a device identifier for a selected well equipment device  101 . As described above, “well equipment devices” includes the equipment and devices used in hydraulic fracturing for oil and gas wells, i.e. “high pressure hydraulic fracturing flow iron,” “frac iron,” or, simply, “iron.” Frac iron can include, for example, a slurry blender, high pressure/volume fracturing pumps, high pressure treating iron, and other pipes, joints, valves, and fittings. For example, frac iron can include swivel joints, pup joints, plug valves, check valves and relief valves. Furthermore, by way of example, frac iron can include any type of ball injector, crow&#39;s foot, air chamber, crossover, hose, pipes/piping, hose loop, ball injector tee body, tee, wye, lateral, ell, check valve, plug valve, wellhead adapter, swivel joint, plug, relief valve, densometer, cross, frac pump, or cement pump. The selected well equipment device is a well equipment device that has previously undergone testing, for example, as described above with respect to the testing module  210 . The certification module  220  can receive a device identifier, for example, responsive to receiving input from the testing interface  150  as entered therein by a testing user  151 . The certification module  220  can also receive a device identifier, for example, responsive to receiving input from a remote user interface as entered therein by a remote user  161 . Furthermore, the certification module  220  can receive a device identifier from the testing module  210  responsive to the testing module  210  having completed execution of the testing operations and the generation and linking of the testing data in the database  170 . The certification module  220  can identify a selected well equipment device responsive to the device identifier and generate and link certification data in database  170 , for example, in certification table  450 , responsive to the testing data. For example, the certification data  450  can include all data as can be entered onto certificate  500  as a summary or other rendering of testing data responsive to testing operations being performed on the well equipment device  101 , for example, a graphical representation of a pressure test  503 . The certification module  220  can include logic to generate charts and data modeling based upon testing data, which is raw data stored, for example, in table  440 . Further examples of summaries or renderings of raw testing data responsive to the testing operations appear on the face of certificate  500 . As a result of the linking operation, the certification data  440  can be readily accessed or queried according to a serial number for a well equipment device. 
     The certification module  220  can also generate certification data in a format responsive the proprietary data table format for the exemplary RFID certificate. For example, certification module  220  may generate certificate data according to specific standards or protocols employed in the proprietary standard, for example, cell size, packet size, header length, payload length, etc. The RFID certificate can be generated so that it is ready to be stored to the media attached to the well equipment without further processing. The certification module  220  may also include logic for rendering graphics stored as certification data, such as the schematics and charts, into a lightweight graphics formats such as vector graphics formats. The RFID certificate, for example, can include all fields available on the paper document, including device identifier  501 , pass or fail grading  502 , tabular summary or rendering of test data  503 , drawing  504 , measured values  505 , and demanded values  506 . The tabular summary or rendering  503  and the drawing  504  can be encoded in lightweight vector graphics formats, for example. 
     Reporting Module  230  and Enterprise Resource Planning Interface 
     As is shown in  FIG. 2 , the reporting module  230  may be a computer program product stored in the non-transitory memory  240  on the central management server  100  and operable on the processor  251  thereof. Computer program product  230  contains instructions that are operable on the processor  251  that cause reporting module  230  and the central management server  100  to perform the operations discussed further herein. 
     The reporting module  230  can interact with the processor  251  to receive or transmit data, instructions, and other information from or to any of the devices connected to I/O  252 . In addition, both the reporting module  230  and the testing module  210  are in communication with the processor  251  and non-transitory memory  240  so that these two modules can pass or return variables between each other according to a common application programming interface (API) or shared global variables being stored on the non-transitory memory  240 , thereby enhancing interoperability and open communication between the modules. Likewise, those skilled in the art will understand that computer program products  230  and  220  are capable of passing, returning, or referencing common variables regardless of whether computer program products are executed on the same processor  251  and that a common API will allow interoperability and open communications as described above. In embodiments discussed below, the reporting module  230  at least interacts with the testing module  210 , certification module  220 , and database  170 . Although remote user interface  160  may be a PC as has been described for testing interface  150 , remote user interface  160  can also be implemented in whole or in part as a user terminal interface on the central management server  100  itself, using a keyboard, display, or media inputs and outputs connecting to the I/O  252 . Remote user interface  160  can also be a lightweight graphical user interface (GUI) operable over a web browser and viewable on any browser-enabled device, such as a PC, smart phone, or other equipment having a processor and computer functionality. 
     The reporting module  230  can receive a device identifier for a selected well equipment device  101 , the selected well equipment device being a well equipment device that has previously undergone testing, for example, as described above with respect to the testing module  210 . The reporting module  230  can receive a device identifier, for example, responsive to receiving input from the testing interface  150  as entered therein by a testing user  151 . The reporting module  230  can also receive a device identifier from any other module, as discussed above. In response to receiving the device identifier, the reporting module  230  can match the device identifier to any desired data in the database  170 , for example, testing data in the database at testing data table  440 , certification data in the certification data table  450 , device library data from the device library table  410 , and test specification data from the specification library  420 . The reporting module, responsive to the device identifier, can return any of the test specification for the selected well equipment device  101 , testing data for a plurality of testing sequences performed on the selected well equipment device  101 , and certificate data for the selected well equipment device  101 , for example, according to the database structure provided in  FIG. 4 . 
     The reporting module  230  may also receive an indication or selection of additional variables for reporting purposes, for example, a part number, work order number, etc. In the event that the reporting module  230  receives an additional variable, the reporting module  230  can or expand or refine the matched data with respect to the additional variable. For example, the reporting module  230  may receive a device identifier, a work order number, and the reporting module  230  will return a list of all certifications, tests, or specifications for that device identifier according to the tests performed under the received work order number. On the other hand, a reporting module  230  may receive a device identifier and a part number, and the reporting module  213  will return a list of all certifications, tests, or specifications for either the selected well device  101  or all well devices tested having the selected the part number. 
     Embodiments of the present invention employing the reporting module  230  are beneficial in that they transform the task of testing and certification—once a costly operational hurdle—into a robust data-point in business and operational management decisions. For example, manufacturers may use embodiments of the reporting module in research and development to better understand wear patterns and rates in real-world applications, to build a better product, and to manage customer relations. As those skilled in the art will appreciate, the reporting module  230  can be a powerful tool in achieving management-level value from systematic testing and certifications, which provides a comprehensive and reliable (i.e., consistent) pool of data pertaining to asset management, inventory management, purchasing, risk management, and other business analytics. Exemplary reports generated by the reporting module  13  are shown in  FIGS. 24-25 . 
     Furthermore, embodiments of the present invention can employ an ERP (Enterprise Resource Planning) interface (not pictured) connected to the I/O of the central management server  100  to provide the foregoing benefits realized by the reporting module, but in a manner that is more fully integrated into enterprise-wide information systems and providing high levels of cross-functional integration, network scalability, and real-time data synchronization. In particular, embodiments of the present invention employ an ERP interface for the purposes of invoicing the testing and certification operations, for example, responsive to work order information entered by a testing user  151  to the testing interface  150  as shown in  FIG. 6A . 
     RFID  130 ,  135 ,  140   
     Furthermore, embodiments of the present invention can achieve some or all of the foregoing objectives by providing a central management server  200  that can communicate with one or more well equipment devices  101 . For example, the central management server  200  can be in communication with the one or more well equipment devices using wireless communication technologies, for example, radio frequency identification (RFID) technologies. The one or more well equipment devices  101  can include an RFID tag  135 , and the central management server  200  can communicate with the RFID tag  135  on the one or more well equipment devices using an RFID reader  130  in communication with the central management server  200  through the I/O  252 . In an embodiment, the RFID tag is a UHF Gen-2 RFID tag that is attached to the frac iron using a clamp designed to be sufficiently robust so that the RFID tag is not affected by the harsh operating conditions of the downhole environment. 
     In an embodiment, the RFID reader  130  and RFID  140  are peripherals to the testing interface  150 , attaching thereto by known connection means in the art, such as a USB cable or cables. In certain embodiments, the RFID reader and RFID writer may be one unit, such as an RFID reader/writer device. 
     The RFID reader  130  can read a device identifier from the RFID tag on a selected well equipment device  101  through radio frequency communication and transmit the device identifier to the central management server  200 . The central management server is positioned to receive the device identifier from the RFID reader  130 . Any of the computer program products discussed herein, such as the testing module  210 , can receive a device identifier responsive to the central management server  200  receiving a device identifier from the RFID reader  130 . An embodiment of a computer-implemented method for using the RFID reader  130  includes the testing user  151  having a handheld and/or remote RFID reader  130  in physical proximity to the selected well equipment device  101  and the RFID tag  135  thereon so that the testing user can interrogate the RFID tag  135  and so that the RFID tag can transmit the device identifier to the RFID reader  130 . 
     The RFID writer  140  can write an RFID certificate to the RFID tag on a selected well equipment device  101  through radio frequency communication and transmit the device identifier to the central management server  200 . The RFID certificate can have the qualities and properties as described herein, preferably including at least a serial number. The central management server is positioned to transmit the RFID certificate or any data included therein to the RFID writer  140  responsive to any of the computer program products discussed herein, such as the certification module  220 . An embodiment of a computer-implemented method for using the RFID writer  140  includes the testing user  151  having a handheld or remote RFID writer  140  in physical proximity to the selected well equipment device  101  and the RFID tag  135  thereon so that the testing user can establish a communication link with the RFID tag  135  and so that the RFID writer can transmit and store the RFD certificate or the information therein to the RFID tag  135 . 
     This application claims priority and is related to U.S. Provisional Patent Application No. 61/330,248 filed Apr. 30, 2010 titled “Machines, Systems, Computer-Implemented Methods, And Computer Program Products To Test And Certify Oil And Gas Equipment,” which is incorporated by reference in its entirety herein. 
     The foregoing has broadly outlined certain features, and technical advantages of the present invention and a detailed description of the invention so that embodiments of the invention may be better understood in light of features and advantages of the invention as described herein, which form the subject of certain claims of the invention. It should be appreciated that the conception and specific embodiments disclosed may be readily utilized as a basis for modifying or designing other structures for carrying out the same purposes of the present invention. It should also be realized that such equivalent constructions do not depart from the invention as set forth in the appended claims. The novel features which are believed to be characteristic of the invention, both as to its organization and method of operation, together with further advantages are better understood from the description when considered in connection with the accompanying figures. It is to be expressly understood, however, that such description and figures are provided for the purpose of illustration and description only and are not intended as a definition of the limits of the present invention. For example, although the example embodiments discussed herein are directed to oil and gas hydraulic fracturing operations, it should be specifically noted that the systems, machines, methods, and computer program products to test and certify well equipment devices may be employed to carry out similar functions for other equipment or devices requiring routine testing and certification, including without limitation, aircraft maintenance and construction, ship maintenance and construction, facilities maintenance and construction, and so on.