Fig. 1. Strain transfer analysis model. (a) Cross section; (b) longitudinal section

Fig. 2. Microelement force diagram of each layer

Fig. 3. Strain transfer rate curves of different colloidal shear modulus (2L=200 mm)

Fig. 4. Effect of strain transfer rate on length of paste section(2L=10,20,30,…,300 mm from center to the sides)

Fig. 5. Low strain transfer section varies with the paste length of fiber (hear modulus increases in turn in the direction of the arrow, L= 150 mm)

Fig. 6. High strain transfer section varies with the paste length of fiber (shear modulus increases in turn in the direction of the arrow, 2L= 300 mm)

Fig. 7. OSI-C distributed high precision frequency domain strain temperature analyzer

Fig. 8. Guhe FITEL-S1778 welding machine

Fig. 9. Fitting curve between theoretical strain and fiber average strain

Fig. 10. Equal strength beams bonded with different lengths of fiber

Fig. 11. Curves of strain transfer rate with different paste lengths. (a) Volume ratio of curing agent to binder is 1∶1; (b) volum ratio of curing agent to binder is 1∶2

Fig. 12. Changes of strain transfer rate with shear modulus of different adhesives prepared by curing agent and binder (volume ratio of 1∶1 and 1∶2). (a) Paste length 2L=200 mm; (b) paste length 2L=150 mm; (c) paste length 2L=100 mm; (d) paste length 2L=50 mm; (e) paste length 2L=30 mm

Fig. 13. Effect of different paste length and shear modulus of different adhesives prepared by curing agent and binder (volume ratio of 1∶1 and 1∶2) on high strain transfer section (2L=200 mm)