Abstract: Crushing is very essential to effective initial cleaning, one of the primary steps in residual film recycling. Crushing equipment has been developed to efficiently break down the film impurities for subsequent cleaning. Existing crushing devices of residual film can often effectively process the loose film and similar materials. But the residual film recovery has shifted from the loose materials to bale recovery in recent years. Furthermore, the film stray round bale is more compact than the bulk material wrapping after the recovery. The mechanical properties are quite different than before. However, it is very limited to the crushing efficiency of the whole bundle of film stray round bale. The large volume, compact winding, and mechanical properties are required to effectively break the whole bundle in the resource utilization of the residual film. In this study, a single-roller square blade crushing device for machine-harvested film-impurities round bale in cotton field was designed to improve the quality of recycled products using sliding cutting. According to the overall structure and working principle, the material properties of the film receiving mixed round bale were combined with the theoretical analysis of the crushing process of the device. The influencing factors were obtained on the crushing quality, including the pushing speed of the push board, the rotating speed of the moving blade roller, and the vertical height of the moving blade roller and the lower blade. The structure and working parameters of the crushing device were also determined, including the curve and shape of the moving and fixed blade edge, the outer diameter of the moving blade roll, three kinds of arrangement mode of the moving blade, and the clearance between the moving and fixed blade. The maximum outer dimension of the broken residual film after unfolding was divided into four distribution ranges for sorting and weighing. In the material classification, the materials with the smaller dimensions and those without collection were all classified into the minimum size ranges. The residual films with the maximum outer dimension within the range of 0,100) mm and ≥500 mm were defined as the over-broken film and over-long film, respectively. These two kinds of residual film were unqualified, while those within the range of 100,300) mm and 300,500) mm were defined as the qualified residual film. The percentage of qualified residual film mass in the sample was the qualified rate of residual film breakage. A three-factor and three-level response surface test was carried out with the qualified rate of broken residual film as the test evaluation index. A systematic analysis was implemented on the influence of each test factor on the performance of the device. A regression model was established for the clearance between the moving blade and the lower blade, the arrangement of the moving blade, the rotational speed of the moving blade roll, and the qualified rate of broken residual film. The optimal combination of parameters was obtained in the device, according to the parameter optimization function of Design-Expert software. The test results show that the main and secondary influencing factors on the pass rate of residual film crushing were the rotating speed of the moving blade roll, the clearance between the moving blade and the lower blade, and the arrangement of the moving blade. Specifically, the clearance between the moving blade and the lower blade was 14 mm, the moving blade arrangement was staggered, the blade roll speed was 165 r/min, and the qualified rate of broken residual film reached the maximum of 69.51%. The average qualified rate of broken residual film was 70.78% after the verification test, where the prediction error of the model was within 2%. The device can be expected to realize the whole bundle broken of film and miscellaneous bundle materials. The crushing quality can fully meet the requirements of film miscella resource utilization. The finding can provide a strong reference to the breaking device for the film and miscellaneous bundle materials in the cotton field.