To compare effects of low frequency pulsed electromagnetic fields on bone quality in growing rats between 1 h and 1.5 h. Thirty male SPF SD rats aged 4 weeks selected, which with the average body weight (115.8± 1.5) g, were divided into three groups according to random number table, 10 rats in each group. Control groups put rats into electromagnetic field device with 1.5 h every day, the other two groups put rats in electromagnetic field for 1 h and 1.5 h with a 50 Hz 0.6 mT intensity pulsed. The body weight of rats was weighed every 2 weeks and detected bone mineral density. Rats were sacrificed after 6 weeks to measure bone mineral density and biomechanical value of the right femur and lumbar vertebrae. Serum osteocalcin (OC) and tartrate-resistant acid phosphatase 5b (TRACP 5b) concentrations were determined by ELISA methods. After the magenta-picric acid staining, the micro tissue structure of the right tibia was observed, and the parameters of trabecular bone were analyzed by IPP 6.0 software. There were no statistical difference in body weight and organ coefficient among each groups at different times. Bone mineral density results showed that the body thickness of the 1.5 h group was significantly increased compared with control group at 6 weeks, and bone mineral density of femoral and vertebra in 1.5 h group were higher than that of in 1 h group. The results of three point femoral bending and vertebral compression test showed that the maximum load value of femur and vertebrae in 1.5 h group increased significantly compared with control group, and the maximum femoral load value in 1.5 h group was significantly higher than that of 1 h group, while there was no difference in elastic modulus values among each groups. Results of serum biochemical indicators showed that level of OC in 1.5 h group was significantly increased compared with control group, and significantly higher than that of 1 h group, while no significant difference in TRACP 5b values among each groups. Bone histomorphometry analysis results showed that there was no statistical difference in trabecular thickness, number and resolution between 1 h group and control group, trabecular bone thickness and number in 1.5 h group were increased, and trabecular bone resolution was decreased; The thickness and number of trabecular bone in 1.5 h group were also significantly increased compared with 1 h group, and the degree of resolution was reduced, and had significant difference between two groups. Intervention of 50 Hz 0.6 mT low frequency pulsed electromagnetic field for 1.5 h could effectively increase peak bone mineral density and bone microstructure in young rats, enhance biomechanical properties of bone, promote concentration of bone formation markers in rat blood. The results indicating that pulsed electromagnetic field could be used as a good way to prevent and treat osteoporosis.