Method and apparatus for nondestructive inspection of interwoven wire fabrics

A method and apparatus for nondestructive inspection of interwoven wire fabric components. The apparatus comprises a probe, a power source, and a display system. The probe is capable of creating a magnetic field for a plurality of wires in an interwoven wire fabric component such that disturbances of the magnetic field caused by the plurality of wires can be detected. The power is a source connected to the probe and is capable of sending an alternating current through the probe to generate the magnetic field for the wire. The display system is connected to the probe and is capable of displaying results from detecting the magnetic field and disturbances of the magnetic field.

BACKGROUND INFORMATION

The present disclosure relates generally to inspecting components and in particular to a method and apparatus for identifying variations in a component. Still more particularly, the present disclosure relates to a method and apparatus for nondestructive inspection of interwoven wire fabrics.

Today's aircraft are being designed and built with greater percentages of composite materials. In some aircraft, up to fifty percent of the structural components are being manufactured with composite materials. Composite materials are tough, light-weight materials. These types of materials may be made by combining two or more dissimilar products, such as fibers and resins, to create a product with improved or exceptional structural properties not present in the original materials.

Composite materials are used in aircraft to meet goals, such as reducing weight and increasing payloads in the aircraft. Further, composite materials also are used because these types of materials have improved fatigue, life, and increased corrosion resistance as compared to other currently used materials.

Although composite materials are lighter and have better mechanical and fatigue properties as compared to aluminum, these types of materials are less electrically conductive and have poor electromagnetic shielding. These features cause poor current dissipation when an electromagnetic effect, such as a lightning strike occurs. Further, composite materials are subject to greater damage due to lightning strikes than traditional aluminum materials used in aircraft.

Specifically, when lightning hits an aircraft, a conductive path on the skin of the aircraft allows the electricity to travel along the skin and exit at some other location on the aircraft. Without an adequate conductive path, arcing and hot spots can occur. These types of effects may char, delaminate, and/or penetrate the skin of the aircraft. As a result, the load bearing characteristics of the structure of the aircraft may be returned. Thus, the lower electrical shielding capability of composite materials increases the likelihood that circuits within the aircraft may be affected by the lightning strike.

One current mechanism used to protect composite skins on aircraft against lightning strike damage, is to include conductive lightning skin protection systems. These types of systems may be present either in or on the composite skins of an aircraft. One type of system used to provide a conductive path on the aircraft is an interwoven wire fabric. With this type of system, wires, such as phosphor-bronze wires are embedded in the top layer of the composite material nearest the wind swept surface. This type of material is commonly used in the fuselage of an aircraft. Other types of systems may include the use of a thin copper foil, such as on the wings of an aircraft using composite materials.

With an interwoven wire fabric system in the fuselage, the wires typically have a thickness range of about 0.003 to about 0.004 inches. Further, these types of wires are spaced apart from each other. The spacing is around one tenth of an inch in a ninety degree mesh pattern.

In inspecting installations of composite skins containing interwoven wire fabric, it is desirable to be able to have these wires not more than a selected distance below the surface of the skin. This distance between the surface and the skin is for economic reasons, and not safety reasons. With respect to economic issues, it is more expensive if the distance to the surface of the skin from the wires is too great. The economic costs are larger with the greater distance because increased damage to layers above the interwoven wire fabric may occur. For example, damage to this layer and layers such as paint may increase with lightning strikes as compared to a smaller distance from the surface of the skin to the wires.

Additionally, it is desirable to determine if bonded repairs on composite panels containing interwoven wire fabrics have a sufficient overlap between the patch material and the current material. The overlap width should be sufficient to allow the transfer of energy from a lightning strike on a bonded repair section into the parent material of the fuselage. The overlap width is the width of the edge of the patch material extends over the parent material. The width is typically about an inch. At the overlap, the repair fabric is on top of the parent material, so that the fabric is essentially doubled up in this region. This width is constant all around the patch area. In inspecting new installations and repairs, it is desirable to be able to make these types of inspections in a nondestructive manner.

SUMMARY

The different advantageous embodiments provide a method and apparatus for nondestructive inspection of interwoven wire fabric components. The apparatus comprises a probe, a power source, and a display system. The probe is capable of creating a magnetic field for a plurality of wires in an interwoven wire fabric component such that disturbances of the magnetic field caused by the plurality of wires can be detected. The power is a source connected to the probe and is capable of sending an alternating current through the probe to generate the magnetic field for the wire. The display system is connected to the probe and is capable of displaying results from detecting the magnetic field and disturbances of the magnetic field.

In one advantageous embodiment, a system for nondestructive inspection of an interwoven wire fabric component comprises a scanner arm, a probe, a scanner, and a computer. The scanner arm is connected to the scanner and is capable of being moved over the interwoven wire fabric component. The probe is connected to the scanner arm and is capable of creating a magnetic field for a plurality of wires in an interwoven wire fabric component such that disturbances of the magnetic field caused by the plurality of wires in response to the magnetic field can be detected. The scanner is capable of moving the scanner arm over the interwoven fabric component. The computer is capable of controlling the scanner to move the scanner arm and capable of receiving signals from the probe, wherein the computer generates results from the signals and presents the results on a display in the data processing system.

In another advantageous embodiment, a method for nondestructive inspection of an interwoven wire fabric component is present. An alternating current at a frequency is sent though a probe coil having a number of coils, a diameter for the number of coils, and a diameter for a wire in the number of coils to generate a first magnetic field that generates a response in a selected number of wires in the interwoven wire fabric component. The probe coil is positioned in a location relative to the interwoven wire fabric component to cause the selected number of wires in the interwoven wire fabric component to generate a second magnetic field. Changes in the first magnetic field in response to the second magnetic field are detected.

DETAILED DESCRIPTION

With reference now to the figures, and in particular with reference toFIG. 1, a diagram of an aircraft is depicted in which an advantageous embodiment may be implemented. Aircraft100is an example of an aircraft in which nondestructive inspection of interwoven wire fabric components may be implemented. In this illustrative example, aircraft100has wings102and104attached to fuselage106. Aircraft100includes wing mounted engine108, wing mounted engine110, and tail112.

The different advantageous embodiments may be implemented to perform nondestructive inspections of interwoven wire fabric components found in portions of aircraft100, such as fuselage106. One or more of the different advantageous embodiments may be used to inspect repairs to interwoven wire fabric components, as well as new installations of these types of components.

Turning now toFIG. 2, a diagram illustrating a cross-section of an aircraft skin including interwoven wire fabric wires is depicted in accordance with an advantageous embodiment. In this example, section200is a cross-section of a skin on a portion of aircraft100inFIG. 1. In particular, section200is a cross-section from the skin of fuselage106inFIG. 1. In this example, section200includes substrate layer202, interwoven wire fabric layer (IWWF)204, surfacer layer206, and paint layer208. In these examples, the different layers in section200are part of the interwoven wire fabric component.

An interwoven wire fabric component is a component from which measurements, such as wire depths or overlapping between wires, are desired. Depending on the implementation, the interwoven wire fabric component may only include interwoven wire fabric layer204, surfacer layer206, and paint layer208. Of course, the interwoven wire fabric component may include other layers in addition to or in place of the ones illustrated in these examples.

Substrate layer202is a composite substrate for the skin of a fuselage in this example. Interwoven wire fabric layer204contains wires210, which provide a conductive path for electromagnetic effects, such as a lightning strike. Surfacer layer206provides a coating or surface for the application of paint layer208.

Section200is an example of a section of a component in which a nondestructive inspection of interwoven wire fabric layer204may be made. In these examples, a distance, such as distance212, is measured to identify a thickness of the dielectric above wires210within interwoven wire fabric layer204. In these examples, the dielectric includes surfacer layer206and paint layer208. The dielectric may include other materials or layers, such as a sealant, a nonconductive primer, or some other combination of those materials along with surfacer layer206and paint layer208.

The thickness of the dielectric layer above wires210is important because the thickness impacts the dissipation of electrical energy from lightning strikes. As distance212increases, greater damage may occur when lightning strikes are encountered. This type of damage is an economic issue rather than a safety issue. The damage caused by lighting strikes is to components, such as paint layer208and surfacer layer206.

In the depicted examples, a thickness of around 0.20 inches for depth212is desirable. Typical dielectric thicknesses are from around 0.002 to 0.018 inches. The different thicknesses depend on the particular color used for paint layer208as well as the part on which paint layer208is applied. In these illustrative embodiments, depth212is around 0.2 inches. An example of a larger depth for depth212is 0.42 inches. This type of thickness in depth212is typically seen after years of service in which additional coats of paint are applied to paint layer208, thereby increasing the thickness of the dielectric layer.

The different advantageous embodiments recognize that in using an eddy current system to measure depths of wires and overlap width in an integrated wire fabric component, it is currently not possible to distinguish between the overlap area and a single thickness of an integrated wire fabric used on a component. The different advantageous embodiments provide a method and apparatus for nondestructive inspection of an interwoven wire fabric component.

Further, the different advantageous embodiments recognize that when the magnetic field generated by the current probe is too small, only individual wires are sensed. Also, if the magnetic field is too small, the gaps between the wires are sensed and read as an infinite depth of wire. Further, moving a probe with a small field only provides noise as the field rises over the wires and then drops again. The different advantageous embodiments also recognize that if a magnetic field generated by an eddy current probe is too large, the probe is unable to sense the presence of the wire because of comparatively large volume of electrically conductive graphite that is present in these types of materials.

The different advantageous embodiments provide a method and apparatus for nondestructive inspection of interwoven wire fabric components. The apparatus comprises a probe, a power source, and a display system. The probe is capable of creating a magnetic field for a plurality of wires in an interwoven wire fabric component such that disturbances of the magnetic field caused by the plurality of wires can be detected. The power is a source connected to the probe and is capable of sending an alternating current through the probe to generate the magnetic field for the wire. The display system is connected to the probe and is capable of displaying results from detecting the magnetic field and disturbances of the magnetic field.

In one advantageous embodiment, a system for nondestructive inspection of an interwoven wire fabric component has an arm that is capable of being moved over the interwoven wire fabric component. A probe connected to the scanner arm is capable of creating a magnetic field for a plurality of wires in an interwoven wire fabric component, such that disturbances of the magnetic field caused by the plurality of wires in response to the magnetic field can be detected. The scanner is present in this system and is capable of moving the scanner arm over the interwoven fabric component. A computer is present in the system and is capable of controlling the scanner to move the scanner arm and capable of receiving signals from the probe, wherein the computer generates results from the signals and presents the results on a display in the data processing system.

In another advantageous embodiment, a method for nondestructive inspection on an interwoven wire fabric component is provided. An alternating current at a frequency is sent though a probe coil having a number of coils, a diameter for the number of coils, and a diameter for a wire in the number of coils to generate a first magnetic field that generates a response in a selected number of wires in the interwoven wire fabric component. The probe coil is positioned in a location relative to the interwoven wire fabric component to cause the selected number of wires in the interwoven wire fabric component to generate a second magnetic field. Changes in the first magnetic field in response to the second magnetic field are detected.

The different illustrative embodiments also include a probe design that may be employed to measure the overlap width of a repair in which an interwoven wire fabric patch is present over an interwoven wire fabric component, such as a fuselage. Further, this probe also provides the ability to measure the thickness of a dielectric over the phosphor-bronze wires located in the interwoven wire fabric. In these examples, the dielectric includes, for example, paint, surfacer, and/or sealant thickness. Of course, other materials may be present in this dielectric depending on the implementation.

Turning now toFIG. 3, a diagram illustrating an apparatus for nondestructive inspection of an interwoven wire fabric component is depicted in accordance with an advantageous embodiment. In this example, probe300is connected to power source302. Power source302generates an alternating current at a frequency that causes probe300to generate a magnetic field. This magnetic field may cause an eddy current within a selected number of wires within interwoven wire fabric component304.

Probe300is designed and/or operated such that the selected number of wires provides a response that causes a disturbance in the magnetic field. The size of the magnetic field generated by probe300is selected to obtain a response from the selected number of wires. In these examples, the number of wires selected is such that the signal or data returned from probe300can be used to identify a depth of the selected wires and/or to identify an overlap of wires within interwoven wire fabric component304.

The changes in the first magnetic field generated by probe300, occurring in response to the second magnetic field, are detected and used to generate results. In other words, the second magnetic field causes a disturbance or change in the first magnetic field that may be quantified. In these examples, the disturbance or change is detected through a change in the inductive reactance for probe300.

These results may be, for example, a depth of the selected number of wires from the surface of interwoven wire fabric component304, or an amount of overlap width between wires in a patch to interwoven wire fabric component304and wires in the original portion of interwoven wire fabric component304.

The disturbances in the first magnetic field in probe300are detected by detection system306. In these examples, detection system306includes circuitry to detect the changes in the magnetic field generated by the flow of an alternating current through probe300. The changes detected are changes in the inductive reactance in probe300. Detection system306may include a display to present the changes in inductive reactance from disturbances to the magnetic field such that a user may see these changes. The changes in inductive reactance may occur as a user moves probe300over different sections of interwoven wire fabric component304.

In this particular example, probe300is a hand held unit that is moveable by a person performing inspections. Detection system306may be a simple component or device that presents changes in the inductive reactance detected in probe300. In this type of implementation, both power source302and detection system306may be located in the same box or unit. Alternatively, detection system306may be more complex and take the form of a computer that may record and store, as well as present data generated by probe300.

Turning now toFIG. 4, a diagram illustrating a scanning apparatus for nondestructive inspection of an interwoven wire fabric component is depicted in accordance with an advantageous embodiment. In this example, system400includes scanner402, arm404, probe406, computer408, and display410. These components in system400are used to provide nondestructive inspection of interwoven wire fabric component412.

In these examples, probe406is mounted on or connected to arm404. Arm404may be moved by scanner402over different sections of interwoven wire fabric component412. Further, scanner402also provides a power source for probe406. In these examples, the power source sends an alternating electric current through probe406at a frequency that causes probe406to generate a magnetic field. This field grows and collapses as the current alternates.

The magnetic field generated by probe406causes eddy currents within wires within interwoven wire fabric component412. These eddy currents result in magnetic field being generated in those wires within interwoven wire fabric component412. The magnetic fields generated in these wires cause disturbances or changes in the magnetic field generated by probe406, as probe406moves along different sections of interwoven wire fabric component412.

Computer408, in these examples, receives the data or signals received from probe406. The data or signals are generated by disturbances to the magnetic field being generated by probe406in response to magnetic fields generated within interwoven wire fabric component412.

Further, computer408also generates instructions to direct movement of arm404by scanner402over different sections of interwoven wire fabric component412. The results of scanning different sections of interwoven wire fabric component412may be displayed in display410. This display may be presented as a color coded display, in which different magnetic field levels are displayed in different colors.

In this manner, a user may see the different wires present as well as an overlap in wires. Further, by displaying the data in different colors, depth information may be conveyed through colors. Further, display410also may display the inductive reactance of probe406as the scanning occurs while probe406is moved over interwoven wire fabric component412in these examples.

Probe300inFIG. 3and probe406inFIG. 4are designed or configured to generate the magnetic fields having a selected size. In these examples, the size of the magnetic field generated by these probes may be configured or selected based on a number of different parameters. Examples of parameters that may be selected include, a frequency of an alternating current, the probe coil in the probe, the number of coils, a diameter for the number of coils, and/or a diameter for the wire in the probe coil to generate a first magnetic field to generate a response in a selected number of wires in the interwoven wire fabric component. Further, in the depicted examples, probes300and406are unshielded. These parameters and other parameters also may be used to select or generate a particular shape for the magnetic field in addition to setting the size of the magnetic field generated by probes300inFIG. 3 and 406inFIG. 4.

Turning now toFIG. 5, a diagram of a scanner arm is depicted in accordance with an advantageous embodiment. In this example, scanner arm500is an example of one implementation of scanner arm404inFIG. 4. In this example, scanner arm500includes base502. Support rod504is attached to base502. Scanner arm500also includes support member506, rod508, and rod510. These components are connected to each other by rotatary joints512,514, and516. Rod510includes clamp518, which holds probe520. Probe520is an example of a probe, such as probe300inFIG. 3or probe406inFIG. 4. These different components form an articulated arm for scanner arm500that can move probe520in three dimensions, along the X-axis, the Y-axis, and the Z-axis.

Scanner arm500includes motors for moving these components and circuits to receive commands directing the movement. These components may be controlled by commands from a device, such as computer408inFIG. 4. The particular depiction of scanner arm500is for purposes of illustration and not meant to limit the architecture or design that may be used to implement scanner arm500.

Turning now toFIG. 6, a diagram of a data processing system is depicted in accordance with an illustrative embodiment of the present invention. In this illustrative example, data processing system600includes communications fabric602, which provides communication between processor unit604, memory606, persistent storage608, communications unit610, input/output (I/O) unit612, and display614.

Processor unit604serves to execute instructions for software that may be loaded into memory606. Processor unit604may be a set of one or more processors or may be a multi-processor core, depending on the particular implementation. Further, processor unit604may be implemented using one or more heterogeneous processor systems in which a main processor is present with secondary processors on a single chip. Memory606, in these examples, may be, for example, a random access memory. Persistent storage608may take various forms depending on the particular implementation. For example, persistent storage608may be, for example, a hard drive, a flash memory, a rewritable optical disk, a rewritable magnetic tape, or some combination of the above.

Communications unit610, in these examples, provides for communications with other data processing systems or devices. In these examples, communications unit610is a network interface card. I/O unit612allows for input and output of data with other devices that may be connected to data processing system600. For example, I/O unit612may provide a connection for user input though a keyboard and mouse. Further, I/O unit612may send output to a printer. Display614provides a mechanism to display information to a user.

Instructions for the operating system and applications or programs are located on persistent storage608. These instructions may be loaded into memory606for execution by processor unit604. The processes of the different embodiments may be performed by processor unit604using computer implemented instructions, which may be located in a memory, such as memory606.

With reference next toFIG. 7, a diagram illustrating the use of a probe to detect wires in an interwoven wire fabric component is depicted in accordance with an advantageous embodiment. In this example, interwoven wire fabric component700includes interwoven wire fabric layer702and dielectric layer704. Probe706receives an alternating current at a selected frequency that generates magnetic field708. Magnetic field708is generated such that the movement of probe706over wires, such as wires710and712will generate a disturbance in magnetic field708that can be detected.

More specifically, magnetic field708creates electrical currents in wires710and712. These currents are referred to as eddy currents. These currents generate magnetic fields714and716in response. Magnetic fields714and716create a disturbance in magnetic field708. This disturbance to magnetic field708may be detected using a measurement circuit connected to probe706. These changes are detected and used to identify the depth of wires710and712below surface718of interwoven wire fabric component700. The disturbance is detected in the change in the inductive reactance in probe706, in these examples.

Reactance, denoted X, is a form of opposition that electronic components exhibit to the passage of alternating current because of capacitance or inductance. When alternating current passes through a component that contains reactance, energy is alternately stored in, and released from, a magnetic field or an electric field. In the case of a magnetic field, the reactance is inductive.

As described above, the design of probe706is such that only a selected number of wires are affected by magnetic field708. In this example, the selected number of wires is two wires, wires710and712. In this illustrative example, wires720,722, and724do not generate a response due to the size and configuration of magnetic field708. In this example, the magnetic field is shown to generate a response into wires within interwoven wire fabric layer702.

In particular, magnetic field708is generated in a manner to match the spacing between two wires in interwoven wire fabric layer702. Of course, the magnetic field may be adjusted to encompass more wires or less wires depending on the particular implementation. The number of wires is selected such that the presence of individual wires within interwoven wire fabric layer702may be detected.

With reference toFIG. 8, a diagram illustrating a cross-section of a wire fabric and overlap of fabric that generate responses to a probe moved over the component is depicted in accordance with an advantageous embodiment. In this particular example, interwoven wire fabric component800is shown as a cross-section.

Section802contains wires for an original portion of interwoven wire fabric component800. Section804contains wires that overlap with each other. The overlap of wires in this section occurs from a patch being placed into interwoven wire fabric component800as part of a repair. Section806contains wires only from the patch. Section808contains no wires in this example.

Turning now toFIG. 9, a response from a probe having a field that is too large is depicted in accordance with an advantageous embodiment. InFIG. 9, graph900contains line902which represents a signal generated by a probe as the probe moves across interwoven wire fabric component800inFIG. 8. In these examples, the signal is for an inductive reactance in the probe.

In this example, the X-axis for graph900represents different locations across interwoven wire fabric component800inFIG. 8. The Y-axis, in these examples, represent values for inductive reactance measured for the probe, as the probe moves across interwoven wire fabric component800inFIG. 8. In these examples, sections904,906,908, and910correspond to sections808,802,804, and806inFIG. 8, respectively. Line902is a straight line because the field is too large. As a result, the probe is unable to provide data to distinguish between the presence or absence of wires within interwoven wire fabric component800inFIG. 8and is sensing the general reactance produced by the skin cross-section, including the substrate.

InFIG. 10, a diagram illustrating a probe response when the probe field is too small is depicted in accordance with an advantageous embodiment. In this example, graph1000contains line1002which represents a signal detected from a probe moving over interwoven wire fabric component800inFIG. 8.

The X-axis of graph1000represents different locations across interwoven wire fabric component800inFIG. 8. The Y-axis in graph1000represents values for inductive reactance measured or detected for the probe as it moves along different positions or locations for interwoven wire fabric component800inFIG. 8. In these examples, the value for different locations is a measurement of inductive reactance for the probe. Sections1004,1006,1008, and1010correspond to sections808,802,804, and806inFIG. 8, respectively.

In this example, the signal provides noise and is unable to provide any indication of the presence or absence of wires within interwoven wire fabric component800inFIG. 8in the corresponding locations.

Turning now toFIG. 11, a diagram illustrating a probe response with a correct magnetic field size is depicted in accordance with an advantageous embodiment. In this particular example, the magnetic field generated by the probe is of a size that provides for an ability to distinguish or identify when wires are present, the depth of the wires as well as when wires between a patch and original portion of an interwoven wire fabric component overlap.

The X-axis represents different positions or locations across interwoven wire fabric component800inFIG. 8. The Y-axis represents the inductive reactance measured for the probe. In this example, line1100within graph1102represents inductive reactance, generated by a probe moving over interwoven wire fabric component800inFIG. 8. Line1100provides a user an ability to identify when a wire is present in an interwoven wire fabric component.

Section1104shows a signal corresponding to section808inFIG. 8. As can be seen, the signal is lower when wire is absent. Section1106corresponds to section802inFIG. 8. This signal indicates that a single layer of wires is present. Section1108of signal1100indicates an overlap between wires that corresponds to section804inFIG. 8. Section1110provides a signal that corresponds to section806inFIG. 8. As can be seen, in these examples, an identification of wires may be made within interwoven wire fabric component800inFIG. 8. Further, the depth or the distance of the wires from the surface may be identified through the signals.

Turning now toFIG. 12, a flowchart of a process for nondestructive inspection of a component containing an interwoven wire fabric layer is depicted in accordance with an advantageous embodiment. The process illustrated inFIG. 12may be implemented in a scanning system, such as system400inFIG. 4. In particular, the different operations may be implemented in a computer, such as computer408inFIG. 4.

The process begins by selecting sections of a component to be measured (operation1200). Thereafter, an unprocessed selection within the selected sections is selected for processing (operation1202). Next, the probe is moved to the selected section (operation1204). In this example, operation1204is accomplished by sending instructions to a scanner to move the arm holding the probe to the appropriate section. A measurement is then made (operation1206).

Thereafter, the results of the measurement are stored (operation1208). Next, a determination is made as to whether an unprocessed section is present (operation1210). If an unprocessed section is present, the process returns to operation1202as described above. Otherwise, a display of measurements is generated (operation1212).

Then, the display of the measurement is presented (operation1214) with the process terminating thereafter. In operation1212, the displayed measurements may be a two dimensional representation of the sections that were probed or measured. The values for the measurements may be represented using color coding. For example, measurements identifying a wire may be presented in one color. The particular intensity or shade of the color may be varied for the depth of the dielectric along those sections. Further, an overlap width between the original portion of the interwoven wire fabric component and a repaired or patched portion on the interwoven wire fabric component also may be identified using a different color. The amount of overlap, also referred to as the overlap width, may be identified based on the width or sections that this color is presented.

The flowcharts and block diagrams in the different depicted embodiments illustrate the architecture, functionality, and operation of some possible implementations of apparatus, methods and computer program products. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified function or functions. In some alternative implementations, the function or functions noted in the block may occur out of the order noted in the figures. For example, in some cases, two blocks shown in succession may be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved.

Thus, the different advantageous embodiments provide a method and apparatus for nondestructive inspection of an interwoven wire fabric component. The apparatus comprises a probe, a power source, and a display system. The probe is capable of creating a magnetic field for a plurality of wires in an interwoven wire fabric component such that disturbances of the magnetic field caused by the plurality of wires can be detected. The power source connected to the probe is capable of sending an alternating current through the probe to generate the magnetic field for the wire. The display system is connected to the probe and is capable of displaying results from detecting the magnetic field and disturbances of the magnetic field.

In one advantageous embodiment, a system for nondestructive inspection of an interwoven wire fabric component comprises a scanner arm, a probe, a scanner, and a computer. The scanner arm is capable of being moved over the interwoven wire fabric component. The probe connected to the scanner arm is capable of creating a magnetic field for a plurality of wires in an interwoven wire fabric component such that disturbances of the magnetic field caused by the plurality of wires in response to the magnetic field can be detected. The scanner is capable of moving the scanner arm over the interwoven fabric component. The computer is capable of controlling the scanner to move the scanner arm and capable of receiving signals from the probe, wherein the computer generates results from the signals and presents the results on a display in the data processing system.

In another advantageous embodiment, a method for nondestructive inspection on an interwoven wire fabric component is present. An alternating current at a frequency is sent though a probe coil having a number of coils, a diameter for the number of coils, and a diameter for a wire in the number of coils to generate a first magnetic field that generates a response in a selected number of wires in the interwoven wire fabric component. The probe coil is position in a location relative to the interwoven wire fabric component to cause the selected number of wires in the interwoven wire fabric component to generate a second magnetic field. Changes in the first magnetic field in response to the second magnetic field are detected.

With these and other advantageous embodiments, inspections of interwoven wire fabric components can be made in a nondestructive manner. The different embodiments allow for identifying depth of wires in interwoven wire fabric components. The embodiments also may be used to identify an amount of overlap between wires in a patch and the wires in the original portions of interwoven wire fabric components.