CFRP composite

Carbon fiber reinforced polymer is a composite material that combines carbon fibers with a polymer matrix, usually epoxy resin. Characterizing CFRP is crucial for designing a microwave-based curing system, as it poses a fundamental challenge. The CFRP composite is composed of multiple layers of carbon fibers, which can be oriented in different directions and are impregnated with epoxy. These layers are stacked together, and after the curing process, the desired mechanical strength of CFRP is achieved. Therefore, to implement the curing stage using microwaves, it is essential to understand the electromagnetic behavior and properties of CFRP. Unlike homogeneous materials, CFRP exhibits complex electromagnetic properties due to its intricate microstructure. The electrical characteristics of CFRP heavily depend on its orientation and lamination. The fundamental structure of multilayer composites includes unidirectional layers. In this type of CFRP, maximum stiffness and strength are achieved in the direction of the carbon fibers. Another commonly used lamination in CFRP composites is the multi-directional layer which offers strength in all directions [Reference Kajfez20]. For this study, we utilized HexPly® 8552 (AS4 fiber) woven carbon preform with a 55% fiber volume. The selected CFRP composite consists of four layers of carbon fiber with a total thickness of 2.8 mm. This CFRP composite is shown in Fig. 2. Understanding the permittivity characteristics of CFRP is essential for detailed design and analysis of its electromagnetic behavior using simulation software. This understanding also aids in quality control and ensures consistent and reliable curing of CFRP. However, measuring the permittivity of CFRP is complex due to its composite nature, where carbon fibers are embedded in a polymer matrix. As a result, various methods have been proposed to determine the permeability of complex materials like CFRP [Reference Kajfez20]. In the CFRP simulations presented in this article, we used the HFSS software and utilized the model provided in the Ansys Granta library, optimizing the values to fit our specific example. Based on this model, another vital parameter to consider in CFRP curing is the conductivity of the material.

Figure 2. Sample of a cured weave sample under test.

Microwave source

As mentioned earlier, the designed system illustrated in Fig. 1 utilizes four separate ports for curing CFRP. Each port is connected to an E-shaped antenna and powered by a 250 W continuous-wave solid-state power amplifier, operating in the frequency range of 2.3–2.7 GHz. This wide frequency range provides the flexibility to adjust the frequency for each port independently, enabling control over the field distribution in the applicator. Additionally, a phase shifter is incorporated at the output of each amplifier, allowing for phase manipulation to engineer the distribution of the electric field inside the applicator. By leveraging these capabilities and employing an optimized control algorithm, it becomes possible to fine-tune the frequency and phase of the electromagnetic wave irradiated inside the material. This allows for an optimized distribution of the electromagnetic field, ensuring homogeneous absorption in the carbon.

Exposure chamber

In the heating system presented in Fig. 1, a multi-mode cavity is used as a heating chamber at 2.45 GHz, with dimensions of $500 \times 500 \times 500\, {\rm mm}^{8}$. To propagate electromagnetic waves inside the chamber, four E-shaped antennas are employed. These antennas are powered by four separate solid-state power amplifiers, serving as microwave sources. The input ports are situated in the middle of each quarter of the cavity’s upper wall, as shown in Fig. 3.

Figure 3. Fabricated multi-mode cavity as applicator.

As previously mentioned, the microwave power within the applicator is distributed through four E-shaped antennas, each driven by amplifiers with the ability to adjust phase, frequency, and power. Figure 4 illustrates the simulated field distribution inside the applicator at a frequency of 2.45 GHz under different phase conditions. As evident from Fig. 4, modifying the phase individually at each input port alters the electric field distribution within the applicator. Consequently, this capacity to control the distribution allows for the regulation of heat distribution, thereby facilitating homogeneous curing.

Figure 4. (a) E-field distribution in the designed multi-mode cavity which powered by four MW port with the ability to separately adjust phase and frequency, (b) E-field distribution in [0, 0, 0, 0] phase pattern, (c) [90, 0, 0, 0] , (d) [90, 0, 90, 0], (e) [0, 90, 180, 270].

Metamaterial matching design

The main challenges of microwave-based CFRP curing are non-uniform heating and weak microwave absorption issues, stemming from complex interactions between the microwave radiation and the conductive nature of the carbon fiber material. Utilizing a multi-mode microwave cavity along with an advanced optimization control loop, as explained in previous sections, can address these challenges by providing a uniform distribution of microwave energy. This approach minimizes the occurrence of hot spots and improves overall heating uniformity. Additionally, incorporating microwave susceptors into the CFRP composite to enhance microwave absorption can further increase the efficiency of the curing process by combining microwave and conduction heating methods. Based on previous research and the approaches discussed, we propose an effective hybrid method for achieving homogeneous heating in CFRP curing. In this method, the CFRP composite is coated with dielectric epoxy, and small resonator parts are placed on it. Subsequently, the coated CFRP is placed in a controllable multi-mode cavity. Figure 5 illustrates the proposed setup for this solution.

Figure 5. (a) Coated CFRP component by metamaterial patch resonators and (b) metamaterial patch resonators arrangement.

According to the periodically structured resonators and the desired frequency, the rectangular resonance patches were designed and simulated using periodic master/slave boundary conditions in HFSS software at 2.45 GHz. As a result, the metallic patches’ layer resonates at the frequency of the incident microwaves within a multi-mode controllable cavity, absorbing the electromagnetic field to produce efficient heating in the CFRP. The considered simulation structure and its equivalent transmission line model are shown in Fig. 6.

Figure 6. (a) Presented structure for CFRP covered by square patch array resonator and (b) equivalent transmission line model.

The analytical equivalent model of square patches is illustrated in Fig. 6b. The equivalent impedance of patches for different incident wave angles is calculated by (1) and (2) [Reference Luukkonen, Simovski, Granet, Goussetis, Lioubtchenko, Raisanen and Tretyakov12, Reference Luukkonen, Costa, Simovski, Monorchio and Tretyakov13]:

(1)\begin{equation} Z_{P,\text{inp}}^{TE} = \frac{j\omega\mu \tan(\beta d)}{\beta} \left( \frac{1}{1 - \frac{2k_{\text{eff}} \alpha \tan(\beta d)}{\beta \left(1 - \frac{1}{\varepsilon_{r+1}} \sin^2 \theta\right)}} \right) {V_{s}\,f_{0}}, \end{equation}

(2)\begin{equation} \alpha = \frac{K_{\text{eff}} D}{\pi} \ln\left(\frac{1}{\sin \frac{\pi \omega}{2D}}\right), \end{equation}

where $ \theta $ is the angle of incidence and $ k $, $ D $, and $ d $, are the wave number, patch width, and dielectric height, respectively. A comparison of the analytical model with HFSS simulations is shown in Fig. 7, with the patches’ dimensions: $ D $ = 22.6 mm, $ w $ (patches space) = 2 mm, $ d $ = 4 mm, ɛ_r (dielectric constant) = 4.4 (FR4).

Figure 7. Comparison of the analytical model with HFSS simulations.

Due to the dependence of the analytical model on the incident wave angle, in a multi-mode cavity, not all patches resonate at the same frequency. Therefore, their absorption rate will be different.

Optimization control unit

Based on the ability to change the frequency and phase, as provided by the power amplifiers, a control loop has been developed to optimize the distribution of the electromagnetic field, consequently achieving homogeneous heat distribution in the carbon fibers. To monitor the carbon fiber baking process, an IR sensor has been utilized for temperature measurement and thermal imaging of the CFRP surface. The control loop manipulates these settings based on the observed feedback. The feedback signal is generated by an infrared (IR) camera placed directly over the target CFRP material. This IR camera records the heating pattern of the CFRP that results from the applied signals. It is important to note the complexity of this feedback loop, which goes far beyond common SISO feedback loops commonly used in mechanical systems, requiring advanced methods of AI. In this way, the overall system is controlled according to the desired heating pattern.

Thermal characterization

The proposed setup in Fig. 1 is simulated using HFSS and Icepack software to investigate the electromagnetic and thermal behavior, respectively. The simulated heat distribution on the CFRP surface is illustrated in Fig. 8a for several different phase and frequency conditions in the frequency range of 2.4–2.7 GHz. Additionally, the experimental results of the presented system under the same phase and frequency conditions are tested in the experimental environment and are shown in Fig. 8b. These results offer a comprehensive view of the effectiveness of the proposed approach. Furthermore, based on the simulation and experimental findings, it can be observed that the development of a control algorithm for phase and frequency at each port could be instrumental in achieving more homogeneous heating in CFRP composites. As seen in the experimental results, the outstanding wave optional distribution in the chamber and its absorption by the patches allows the implementation of the optimal algorithm to achieve a homogeneous process.

Figure 8. Heat distribution in surface of CFRP: (a) simulation results and (b) experimental results (captured using an optical sensor).

Mechanical characterization

In this section, the effects of microwave curing methods with various curing cycles on the mechanical properties of unidirectional CFRPs are evaluated and compared with a CFRP composite cured using a conventional oven as the reference (as Table 1). The stress and strain are two important parameters to investigate mechanical behavior of materials and were calculated according to the ASTM D790 standard (Fig. 9).

Figure 9. Experimental ASTM D790 standard test setup.

Table 1. Samples of cured CFRPs for studying mechanical properties

From the obtained stress–strain curves, we extracted the following results: max stress (the point at which the first significant damage occurred and the specimen lost structural integrity), max strain (the strain corresponding to the max stress), and Young’s Modulus as the material’s stiffness (the slope of the stress–strain curve). The averages of these values for all materials are compared in Table 2. According to Table 2, the highest max stress was observed in both the oven-cured and 60-min microwave-cured composites, with minimal differences compared to others. The oven-cured composite displayed the highest strain at failure but also exhibited the lowest stiffness.

Table 2. Calculated mechanical properties of cured CFRP samples