It is a known fact that composite panels are used in in all walks of life including the manufacture of anti-ballistic gear which is used by defense systems to protect human beings, vehicles and objects from ballistic damage. It is conventional practice for an organization supplying anti-ballistic gear to provide long term assurances of performance to the agencies procuring such composite panels. The time period for this performance assurance varies from two years to ten years. The performance assurance provided is simply based on the sample testing and ballistic testing methods to test if the manufacturing process parameters such as pressure, temperature, material tolerances, humidity, room temperature have been adhered to. Moreover, manufacturing process parameters such as pressure and temperature can be measured only on the surface of the composite panel and not at the interfaces. The interfaces of a composite panel constitute the intra layers of the composite structure forming the composite panel. Pursuant to such testing most manufactures have still not been able to identify a material change to composite panels manufactured. It is part of existing practice to follow the same process steps and parameters in manufacturing the panels and assume that all interfaces of the panel are subjected to the same parameters and therefore exhibit the same characteristics. These assumptions are not always true for panels which are made out of different types of materials like ceramic and Aramid. Moreover, hard materials like ceramic have manufacturing tolerances and surface irregularities which hinder proper interface bonding.
Composite panels are subjected during their lifetime to external forces such as varying environmental conditions. Additionally, they may also be subject to external forces such as rough use by the user of the composite panel. This holds especially true for composite panels used by the defense systems as these composite panels could be subjected to external forces such as varying environmental conditions and rough-use conditions arising out of the professional hazards involved. As a result it is likely that the material properties which contribute to the structural health of these panels can change or deteriorate. This can happen as a result of their exposure to changing external forces exerted upon them when they are use.
During the life time of these composite panels, they are exposed to extreme environmental conditions and other dynamic and static forces such as:
a) Exposure to temperature between the range of −40éC to +90éC
b) Swift change in humidity from 0 to 100%
c) Immersion in sea water and river water
d) Exposure to direct sun light or infrared or ultra violet rays
e) Highest order of vibrations during transportation
f) Swift changes in altitude pressure
g) Accidental exposure of the composite panel to hard surfaces.
h) Electric and magnetic fields
All of the aforementioned environmental effects cause a change to the material properties which contributes to the structural health of composite panels thereby causing a deterioration in its performance.
Additionally, by their very nature, such composite panels are subject to distortion due to ballistic damage and other forms of impact based damage. These forms of damage cause cracking, delamination and to a very large extent causes a change in the physical and material characteristics of the composite panel. Once a composite panel becomes damaged, it results in a drastic decrease to its impact resistance properties and anti-ballistic capabilities thereby affecting its performance.
The inventor has developed a system and method to monitor the changes in material properties and at the interfaces by monitoring changes in intra-layer properties such as the breakages in ceramics or other hard layers and the interlayer bonding properties (delamination of layers because of environmental and usage and storage depended conditions) of composites thereby determining the changes in the structural health of the composites.
The method involves the transmission of wave packets from one end of the composite panel which are subsequently received at the other end of the composite panel at selected frequencies by way of using sensors which are embedded into the composite panel. A wave packet is a short burst of a localized wave action that travels as a unit. Based on the structural health condition of the medium, the following wave characteristics of these wave packets are thereafter measured:
a. Travel time
b. Amplitude
c. Phase
d. Shape
A part of each wave packet transmitted gets attenuated. The extent of attenuation of each wave packet depends on the material properties of the medium such as the strength of the composite panel and its intra-layer and inter layer bonding. These wave packets take time to reach the receiver and their travel time depends on the material properties such as interlayer bonding (de-lamination), distortion of individual or multiple panels (distortion) or intra layer strength (breakages) of the composite panels which contribute to the structural health of the medium. The wave packets undergo reflections at the boundaries of the composite panel before reaching the receiver because of which the travel time may increase thereby also resulting in a change in the amplitude of the wave packets. Each wave packet may also change its phase and shape depending on the material properties of composite panel and the relative position of the sensors. The final wave packet reaching the receivers is therefore the sum of each individual wave packet reaching the receivers at the same time.
Alternatively, one can use two or more receivers at the same time. The use of additional receivers allows one to determine whether there is any difference in the material properties of the path through which these waves travel. If there is any difference in the material properties of the path through which these waves travel, then there would be a difference in the wave characteristics of each of these waves received by the sensor. This would in-turn help in identifying that there is change in the structural health of the composite panel.
The aforementioned characteristics of the wave packet are influenced by the medium that it travels through. These material characteristics are reflected in the properties of the received signal. Using several receiver sensors at the same time it is possible to map any changes in the structural health of the composite panel.
The following are the steps involved in determining the appropriate wave packet to be sent through the composite panel in order to detect any change in the structural health of a composite panel.
Step One: Determination of Pass Frequency of the Medium:
The method involves the propagation of continuous periodic waves through a composite panel. The composite panel acts as a band pass filter as it allows propagation of waves which are part of the continuous periodic waves of certain frequencies and attenuates or suppresses all other waves which do not belong to that frequency range. This frequency at which the waves propagate with less difficulty from transmitter to the receiver is called the pass frequency (Pass Frequency).
This Pass Frequency depends on the material properties of the composite panel and the position of the sensors. The Pass Frequency changes if the material properties of the composite panel change. Thus, any change in the Pass Frequency indicates a change in the material properties as the path through which the waves have travelled has been materially altered. The strength of the wave propagated depends on the relative positions of the transmitter and the receiver. As a number of sensors can be embedded into the composite panel as indicated above under the heading ‘field of the invention_, the signals received by each sensor differ in frequency, amplitude and phase due to the relative position of the sensor used to transmit the signal and the sensor used to receive the signal in the composite panel. The Pass Frequency is thereafter determined by plotting the amplitude and phase of these signals received by the sensor receiving the signal as a function of input signal frequency. The result obtained consists of waves of different amplitude and the wave frequency of the wave with the highest amplitude is selected in order to determine the Pass Frequency. The Pass Frequency is thereafter selected for further analysis.
Step Two: Use of Wave Packets at Selected Frequencies for Characterization of the Composite Panel:
Once the Pass Frequency has been determined, wave packets of that particular Pass Frequency are transmitted into the composite panel. The wave characteristics such as amplitude, shape, phase and travel time of the continuous periodic wave and wave packets of that Pass Frequency are measured in order to find any change in the structural health of the composite panels. Transmitting a wave packet through the transmitter and measuring the time taken for it to reach a receiver, one can calculate the velocity of the wave packet travelled through the medium. The speed, amplitude or attenuation of this wave packet is a measure of the quality or state of the medium. Similarly, the shape or distortion in the received wave packet is a measure of the number of reflections it has undergone and medium it has travelled. The wave packet samples the properties of the medium through which it is travelling and delivers the wave characteristics of final wave packet to the receiver in the form of amplitude, shape and phase. These properties of received wave packets are measured at different points in time in the service life of the composite panel.
Any changes in the interlayer bonding (de-lamination), distortion of individual or multiple panels (distortion) or intra layer strength (breakages) of composite panels directly affects the strength of the panels. Such delamination, distortion or breakages influence the wave characteristics of such waves passing through the composite panel. The changes in the characteristics of the composite panels resulting from such delamination, distortion or breakages also affect the propagation of continuous periodic waves or wave packets of a particular Pass Frequency. The changes in intra-layer structural integrity, interlayer spacing or interlayer bonding or breakages or micro cracks in the panel also changes its wave characteristics. The developed method makes use of the wave characteristics of wave packets across the panel to enable the detecting of such changes over time. These changes can be measured and recorded as and when required and compared with the original data recorded immediately after manufacturing and before supplying the composite panel to the customer.
When continuous periodic waves are propagated through a composite panel, the resonance and the wave characteristics of these waves being propagated are measured by using sensors embedded within the panel or placed on the surface of the panel and suitable measurement equipment. Similarly, the travel time is also measured for wave packets using sensors placed at different locations. The travel time of these wave packets varies as each signal reaches different sensors at a different time. These wave packets are affected by the material properties of the medium through which they are travelling, thus providing information on the strength and properties of the composite panel as they travel. As a result, the amplitude, phase and shape of these wave packets vary based on the current condition of the composite panel. The results obtained after measuring such wave characteristics and the travel time of these wave packets are recorded before the composite panels are supplied to the customer. All these properties of the wave packet are recorded as ‘Signature Properties_ of that particular composite panel. Signature Properties are therefore defined as those inherent properties of the wave packet travelling through the composite panel recorded subsequent to the manufacture of the composite panel. Such Signature Properties are an indication of material properties such as the interlayer and the intra-layer bonding or lamination strength of the composite panel. Any change to the Signature Properties would be an indication of distortion or breakage of one or more layers of the composite panel.
The present invention is aimed at detecting any changes in the structural health of these composite panels as a result of various external conditions. Initial baseline tests are conducted in order to create a standard result for a composite panel, and the wave characteristics of the composite panel at the time of manufacture are recorded by the manufacturer. The composite panel is then tested by the manufacturer after a certain period of time and the wave characteristics of the composite panel are recorded again and compared with the standard results. These subsequently Recorded Properties are referred to herein as ‘Recorded Properties_. More specifically, Recorded Properties are therefore defined as those properties of the wave packet travelling through the composite panel recorded at any time after the supply of the composite panel by the manufacturer to any person. Any significant difference in the recorded results from the standard results would imply that the composite panels have undergone a structural or material change such as de-lamination, distortion or breakage or the material at the molecular level and that they may not be accordingly fit for use.
The following are the conventional methods of detecting or analyzing the health condition of a composite material:
1. Embedding fiber optic sensors for strain measurement
2. Microelectromechanical system (MEMS) accelerometers for vibration measurement
3. Active ultrasonics
4. Passive acoustic emission monitoring, and
5. Electromechanical impedance measurements
Furthermore, the use of ultrasonic guided waves for nondestructive evaluation of structures is rapidly expanding due to increased understanding of the underlying wave mechanics and improvements in sensors and signal processing. These methods have been developed mainly with regard to identifying any structural damage to a single layer in the composite. However, none of the above methods provides for an inbuilt system to monitor and analyze the structural health of the composite material as a whole.
The following inventions have been identified as possible prior art to the present invention:
The invention relates to a layer with an embedded network of distributed sensors and actuators that can be surface mounted or embedded in a composite structure for monitoring its structural condition and for detecting anomalies in the hosting metallic or composite structures.
The system comprises the following:
Working:
The aforementioned invention deals with a system consisting of a dielectric substrate or a network of sensors and the method adopted in the same is completely different from that of the present invention wherein sensors, actuators or impulse generators are used to detect the resonance properties of the composite panel and not the properties of the dielectric layer as mentioned in the prior art. The disadvantage of the aforementioned invention in comparison to the subject invention is that it employs a large number of sensors in combination with conducting material for conducting signals within the composite material. The subject invention can be worked by using not more than two sensors to produce the desired result of detecting a change to the structural health of a composite panel, and without the necessity of adding any conducting material for conducting signals within the composite material.
The system comprises the following:
Working:
The aforementioned system and method deals with the vibration of the entire composite and also consists of an environmental model which calibrates the results considering the external environmental influence on the composite material. The present invention does not involve any vibration of the composite panel but deals with the measurement of the wave characteristics of a continuous periodic wave and wave packets of a particular Pass Frequency in order to determine the structural health of the composite panel. The objective of the aforementioned invention is to determine the structural damage to the composite panel by monitoring the extent of structural damping. The disadvantage of the aforementioned invention is that the sensors are placed on the surface of the composite structure which will not enable a user to measure the intra-layer properties of the composite structure.
U.S. Pat. No. 4,983,034 deals with providing a system and method for the measurement of distributed strain well suited for use in sensing the strain of a composite structure.
The invention consists of:
a) A composite structure comprising of composite material
b) An optical fiber which is embedded into the composite material
Working:
According to the invention there is, therefore, provided a system, method, process and apparatus to detect any change in the structural health of a composite panel
The description of the preferred embodiment is meant to demonstrate the broad working principles of the invention without limitation as to possible adaptations, extensions, applications etc., which would be obvious to a person skilled in the art. In the interest of brevity and for the purposes of exemplary explanation, references have been made to a system, depicted in
Any difference in the wave characteristics of the signals received by each sensor pairs R1:R6 or R2:R5 or R3:R4 indicates a difference in the change in the material properties of the path through which the waves have travelled to reach each sensor.
The line in the plot which has been designated as magnitude MILO is an indication of the signal transmitted by the transmitter sensor in the centre to the receiver sensor at the left edge.
The line in the plot which has been designated as magnitude MIRO is an indication of the signal transmitted by the transmitter sensor in the centre to the receiver sensor at the right edge.
Components of the structural health monitoring system for detecting the changes in the material properties of a composite panel:
The Structural Health monitoring system comprises the following:
Wherein the sensors are placed as desired within or on the surface of the composite panel. The sensors can be surface mounted or placed internally at any position within the same layer or different layers in the composite panel.
Wherein the sensors can act as a Transmitter sensor
Wherein the sensors can act as a Receiver sensor
Wherein the pre-amplifier pre-amplifies the signals received by the receiver sensor
Wherein the signal recovery unit recovers the signal amplified by the pre-amplifier.
Wherein the signal processing unit processes the signal recovered by the pre-amplifier.
Wherein the measurement equipment measures wave characteristics such as amplitude, phase, shape and travel time of the signal processed by the signal processing unite.
Wherein the control unit is connected to the Receiver sensor through an electronic interface
Working of the Structural Health Monitoring System
The method by which the invention detects the structural health of the composite panel is as follows:
The receiver sensor receives the signal from the wave packet at a selected Pass Frequency transmitted into the composite panel through the transmitter sensor.
A working embodiment of the invention for the purposes of detecting the structural health of a composite panel is disclosed below. The working embodiment is illustrated with the assistance of
Number | Date | Country | Kind |
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201641005836 | Feb 2016 | IN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2017/050916 | 2/17/2017 | WO | 00 |