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5 CONCEPTION AND DESIGN A different paradigm:As every mechanical part,a composite part has to withstand loadings.In addition,the conception process has to extend over a range much larger than for a component made of "pre-established"material.In fact, For isotropic materials,the classical process of conception consists of selection of an existing material and then design of the piece. For a component made of composites,the designer "creates"the material based on the functional requirements.The designer chooses the reinforce- ment,the matrix,and the process for curing. Following that the designer must define the component architecture,i.e.,the arrangement and dimensions of plies,the representation of these on the designs, etc.These subjects are covered in this chapter. 5.1 DESIGN OF A COMPOSITE PIECE The following characteristic properties always have to be kept in mind by the designer: Fiber orientation enables the optimization of the mechanical behavior along a specific direction. The material is elastic up to rupture.It cannot yield by local plastic deformation as can classical metallic materials. Fatigue resistance is excellent. A Very Good Fatigue Resistance The specific fatigue resistance is expressed by the ratio (o/p),with p being the specific mass.For composite materials,this specific resistance is three times higher than for aluminum alloys and two times higher than that of high strength steel and titanium alloys because the fatigue resistance is equal to 90%of the static fracture strength for a composite,instead of 35%for aluminum alloys and 50% for steels and titanium alloys (see Figure 5.1).' TSee Section 5.4.4. 2003 by CRC Press LLC
5 CONCEPTION AND DESIGN A different paradigm: As every mechanical part, a composite part has to withstand loadings. In addition, the conception process has to extend over a range much larger than for a component made of “pre-established” material. In fact, � For isotropic materials, the classical process of conception consists of selection of an existing material and then design of the piece. � For a component made of composites, the designer “creates” the material based on the functional requirements. The designer chooses the reinforcement, the matrix, and the process for curing. Following that the designer must define the component architecture, i.e., the arrangement and dimensions of plies, the representation of these on the designs, etc. These subjects are covered in this chapter. 5.1 DESIGN OF A COMPOSITE PIECE The following characteristic properties always have to be kept in mind by the designer: � Fiber orientation enables the optimization of the mechanical behavior along a specific direction. � The material is elastic up to rupture. It cannot yield by local plastic deformation as can classical metallic materials. � Fatigue resistance is excellent. A Very Good Fatigue Resistance The specific fatigue resistance is expressed by the ratio (s/r), with r being the specific mass. For composite materials, this specific resistance is three times higher than for aluminum alloys and two times higher than that of high strength steel and titanium alloys because the fatigue resistance is equal to 90% of the static fracture strength for a composite, instead of 35% for aluminum alloys and 50% for steels and titanium alloys (see Figure 5.1).1 1 See Section 5.4.4. TX846_Frame_C05 Page 69 Monday, November 18, 2002 12:09 PM © 2003 by CRC Press LLC
rupture aluminum alloy unidirectional composite number of cycles number of cycles Figure 5.1 Comparison of Fatigue Behavior Between Composite and Aluminum The percent elongation is not the same as that for metals (attention should be paid to the metal/composite joints). Complex forms can be easily molded. It is possible to reduce the number of parts and to limit the amount of processing work. One must adapt the classical techniques of attachments and take into account their induced problems:fragility,delustering,fatigue,thermal stresses. 5.1.1 Guidelines for Values for Predesign Figure 5.2 shows a comparison between different materials,which can help in the choice of composite in the predesign phase. Figure 5.3 allows the comparison of principal specific properties of fibers which make up the plies.The specific modulus and specific strength are presented in the spirit of lightweight structural materials. The safety factors are defined to take care of uncertainties on The magnitude of mechanical characteristics of reinforcement and matrix The stress concentrations The imperfection of the hypotheses for calculation The fabrication process The aging of materials The orders of magnitude of safety factors are as follows: High volume composites: Static loading short duration: 2 long duration: 4 Intermittent loading over long term: 4 Cyclic loading: 5 Impact loading: 10 High performance composites: 13to1.8 2003 by CRC Press LLC
� The percent elongation is not the same as that for metals (attention should be paid to the metal/composite joints). � Complex forms can be easily molded. � It is possible to reduce the number of parts and to limit the amount of processing work. � One must adapt the classical techniques of attachments and take into account their induced problems: fragility, delustering, fatigue, thermal stresses. 5.1.1 Guidelines for Values for Predesign Figure 5.2 shows a comparison between different materials, which can help in the choice of composite in the predesign phase. Figure 5.3 allows the comparison of principal specific properties of fibers which make up the plies. The specific modulus and specific strength are presented in the spirit of lightweight structural materials. The safety factors are defined to take care of uncertainties on � The magnitude of mechanical characteristics of reinforcement and matrix � The stress concentrations � The imperfection of the hypotheses for calculation � The fabrication process � The aging of materials The orders of magnitude of safety factors are as follows: Figure 5.1 Comparison of Fatigue Behavior Between Composite and Aluminum High volume composites: Static loading short duration: 2 long duration: 4 Intermittent loading over long term: 4 Cyclic loading: 5 Impact loading: 10 High performance composites: 1.3 to 1.8 TX846_Frame_C05 Page 70 Monday, November 18, 2002 12:09 PM © 2003 by CRC Press LLC
density 1000 10.000 (kg/m3) wood 100 aluminum composites steel and thermoplastics concrete titanium tensile fracture strength (MPa) 100 1000 10,000 10 Wood light alloys 2 concrete steels composites thermoplastics modulus of elasticity 10,000 100.000 1.000.000 (MPa)1000l 1 sees thermoplastics wood concrete aluminum titanium steel composites price per unit mass 1994 2 20 200 600 ($kg) 1 ▣steels and aluminum alloys titanium 7 thermoplastics Kevlar-carbon glass composites boron Figure 5.2 Comparison of Characteristics of Different Materials aluminum alloys Eglass Kevlar 49 High strength carbon High modulus carbon boron 风 specific modulus of elasticity tensile strength specific tensile modulus density density strength Figure 5.3 Specific Characteristics of Different Fibers 2003 by CRC Press LLC
Figure 5.2 Comparison of Characteristics of Different Materials Figure 5.3 Specific Characteristics of Different Fibers TX846_Frame_C05 Page 71 Monday, November 18, 2002 12:09 PM © 2003 by CRC Press LLC
impregnated mesh separators Figure 5.4 Unidirectional Layer 5.2 THE LAMINATE Recall that laminates result in the superposition of many layers,or plies,or sheets, made of unidirectional layers,fabrics or mats,with proper orientations in each ply.This is the operation of hand-lay-up. 5.2.1 Unidirectional Layers and Fabrics Unidirectional layers are as shown in Figure 5.4.The advantages of unidirec- tional layers are: They have high rigidity (maximum number of fibers in one direction). The ply can be used to wrap over long distance.Then the load transmission of the fibers is continuous over large distance. ■They have less waste. The disadvantages of unidirectional layers are The time for wrapping is long. One cannot cover complex shapes using wrapping Example:Carbon/epoxy unidirectionals:Width 300 or 1000 mm,preimpreg- nated with resin;usable over a few years when stored at cold temperature (-18C). Fabrics can be found in rolls in dry form or impregnated with resin (Figure 5.5). The advantages of fabrics are Reduced wrapping time Possibility to shape complex form using the deformation of the fabric Possibility to combine different types of fibers in the same fabric The disadvantages of fabrics are Lower modulus and strength than the case of unidirectionals Larger amount of waste material after cutting Requirement of joints when wrapping large parts 2003 by CRC Press LLC
5.2 THE LAMINATE Recall that laminates result in the superposition of many layers, or plies, or sheets, made of unidirectional layers, fabrics or mats, with proper orientations in each ply. This is the operation of hand-lay-up. 5.2.1 Unidirectional Layers and Fabrics Unidirectional layers are as shown in Figure 5.4. The advantages of unidirectional layers are: � They have high rigidity (maximum number of fibers in one direction). � The ply can be used to wrap over long distance. Then the load transmission of the fibers is continuous over large distance. � They have less waste. The disadvantages of unidirectional layers are � The time for wrapping is long. � One cannot cover complex shapes using wrapping. Example: Carbon/epoxy unidirectionals: Width 300 or 1000 mm, preimpregnated with resin; usable over a few years when stored at cold temperature (–18∞C). Fabrics can be found in rolls in dry form or impregnated with resin (Figure 5.5). The advantages of fabrics are � Reduced wrapping time � Possibility to shape complex form using the deformation of the fabric � Possibility to combine different types of fibers in the same fabric The disadvantages of fabrics are � Lower modulus and strength than the case of unidirectionals � Larger amount of waste material after cutting � Requirement of joints when wrapping large parts Figure 5.4 Unidirectional Layer TX846_Frame_C05 Page 72 Monday, November 18, 2002 12:09 PM © 2003 by CRC Press LLC
satin tabnc Figure 5.5 A Fabric Layer 5.2.2 Importance of Ply Orientation One of the fundamental advantages of laminates is their ability to adapt and control the orientation of fibers so that the material can best resist loadings.It is therefore important to know how the plies contribute to the laminate resistance,taking into account their relative orientation with respect to the loading direction.Figures 5.6 through 5.9 show the favorable situations and those that should be avoided. Recall the Mohr circle: normal stresses shear stresses cf.for example the stress state below and the associated Mohr circle Gy In Figure 5.7,the Mohr circle for stresses shows that the 45fibers support the compression,o=-t(t is the arithmetic value of shear stress),while the resin supports the tension,o2=t,with low fracture limit.The fibers in Figure 5.8 support the tension,o=t,whereas the resin supports the compression,o2=-t.In Figure 5.9,one has deposited the fibers at 45and-45.Taking into account the previous remarks,one observes that the 45fibers can support the tension o=t, whereas the -45 fibers can support the compression,02=-t.The resin is less loaded than previously. 5.2.3 Code to Represent a Laminate 5.2.3.1 Normalized Orientation Considering the working mode of the plies as discussed in the previous section, the most frequently used orientations are represented as in Figure 5.10.The direction called "0"corresponds to either the main loading direction,a preferred direction of the piece under consideration,or the axis of the chosen coordinates. Note:One also finds in real applications plies with orientations +30 and +60. 2003 by CRC Press LLC
5.2.2 Importance of Ply Orientation One of the fundamental advantages of laminates is their ability to adapt and control the orientation of fibers so that the material can best resist loadings. It is therefore important to know how the plies contribute to the laminate resistance, taking into account their relative orientation with respect to the loading direction. Figures 5.6 through 5.9 show the favorable situations and those that should be avoided. Recall the Mohr circle: cf. for example the stress state below and the associated Mohr circle In Figure 5.7, the Mohr circle for stresses shows that the 45∞fibers support the compression, s1 = -t (t is the arithmetic value of shear stress), while the resin supports the tension, s2 = t, with low fracture limit. The fibers in Figure 5.8 support the tension, s1 = t, whereas the resin supports the compression, s2 = -t. In Figure 5.9, one has deposited the fibers at 45∞and –45∞. Taking into account the previous remarks, one observes that the 45∞fibers can support the tension s1 = t, whereas the -45∞ fibers can support the compression, s2 = -t. The resin is less loaded than previously. 5.2.3 Code to Represent a Laminate 5.2.3.1 Normalized Orientation Considering the working mode of the plies as discussed in the previous section, the most frequently used orientations are represented as in Figure 5.10. The direction called “0∞” corresponds to either the main loading direction, a preferred direction of the piece under consideration, or the axis of the chosen coordinates. Note: One also finds in real applications plies with orientations ±30∞ and ±60∞. Figure 5.5 A Fabric Layer TX846_Frame_C05 Page 73 Monday, November 18, 2002 12:09 PM © 2003 by CRC Press LLC
