Abstract:In this study, an arc-shaped suction slot was designed for a pneumatic compact spinning system with a lattice apron. A model was built via mechanical analysis of a fibrous strand in an arc-shaped suction slot to calculate additional twists inserted during condensing. The equations can be solved by using the Runge–Kutta method. The simulation results showed that negative pressure and frictional coefficient of the lattice apron and the fibrous strand have significant effects on additional twists of the strand in… Show more
“…The derivation and calculation of tension T in the linear-shaped suction slot is similar to that in an arc-shaped suction slot, which was presented in our previous work. 1 The linear-shaped suction slot is on the curved surface R. The lattice apron covers the surface that the fiber strand moves upon the apron when spinning. Take a small segment of the fiber strand ds at point O in the suction slot, as shown in Figure 5.…”
Section: Drag Force F Dmentioning
confidence: 99%
“…On this plane, dθ is the central angle corresponding to d s on the plane Y 1 OZ, (unit: rad), therefore, the following can be obtained: Figure 6.Diagram of arc AC 1 on the plane Y 1 OZ. 1 …”
Section: Mathematical Modelmentioning
confidence: 99%
“…A clear understanding of the compact spinning mechanism is conducive to produce higher quality yarn. At present, research on compact spinning mainly focuses on the additional twist mechanism, 1,2 the airflow field, [3][4][5] and the structure and performance of the compact spun yarn compared with the conventional spun yarns. [6][7][8][9][10][11] In perforated-lattice negative-pressure type compact spinning, the twist of the compact yarn is about 3-10% higher than that of ring-spun yarn under the same spinning conditions.…”
The twist mechanism of the fiber strand in the condensing zone in compact spinning is complex. This paper proposes a dynamic model to evaluate the additional twist of the fiber strands. Based on the flow simulation in the condensing zone, the fiber trajectory in the suction slot was simulated and obtained. Several spinning parameters such as suction slot angle, suction slot width, negative pressure, and shape of suction slot, were varied to show their effects on the additional twist. The simulation results indicated that by increasing the suction slot angle from 5° to 10° the additional twist increased significantly. Higher negative pressure also leads to an increase in the additional twist. The suction slot width has a greater effect on the fiber trajectory than on the additional twist. An arc-shape suction slot increased the additional twist compared with a linear-shape one. An experimental test conducted revealed a precise agreement with the simulation results.
“…The derivation and calculation of tension T in the linear-shaped suction slot is similar to that in an arc-shaped suction slot, which was presented in our previous work. 1 The linear-shaped suction slot is on the curved surface R. The lattice apron covers the surface that the fiber strand moves upon the apron when spinning. Take a small segment of the fiber strand ds at point O in the suction slot, as shown in Figure 5.…”
Section: Drag Force F Dmentioning
confidence: 99%
“…On this plane, dθ is the central angle corresponding to d s on the plane Y 1 OZ, (unit: rad), therefore, the following can be obtained: Figure 6.Diagram of arc AC 1 on the plane Y 1 OZ. 1 …”
Section: Mathematical Modelmentioning
confidence: 99%
“…A clear understanding of the compact spinning mechanism is conducive to produce higher quality yarn. At present, research on compact spinning mainly focuses on the additional twist mechanism, 1,2 the airflow field, [3][4][5] and the structure and performance of the compact spun yarn compared with the conventional spun yarns. [6][7][8][9][10][11] In perforated-lattice negative-pressure type compact spinning, the twist of the compact yarn is about 3-10% higher than that of ring-spun yarn under the same spinning conditions.…”
The twist mechanism of the fiber strand in the condensing zone in compact spinning is complex. This paper proposes a dynamic model to evaluate the additional twist of the fiber strands. Based on the flow simulation in the condensing zone, the fiber trajectory in the suction slot was simulated and obtained. Several spinning parameters such as suction slot angle, suction slot width, negative pressure, and shape of suction slot, were varied to show their effects on the additional twist. The simulation results indicated that by increasing the suction slot angle from 5° to 10° the additional twist increased significantly. Higher negative pressure also leads to an increase in the additional twist. The suction slot width has a greater effect on the fiber trajectory than on the additional twist. An arc-shape suction slot increased the additional twist compared with a linear-shape one. An experimental test conducted revealed a precise agreement with the simulation results.
“…This technique is implemented using negative pressure airflow to condense the fiber bundle for eliminating the spinning triangle and improve the yarn qualities [1][2][3]. Compact spinning with lattice apron is the most widely used pneumatic compact spinning system at present, mainly including three-line compact spinning (TLCS) and fourline compact spinning [4][5][6][7][8]. Nevertheless, the compact spinning systems with lattice apron is considered expensive due to the high energy consumption during the spinning process [1].…”
“…A detailed study was conducted by Han et al [45] on simulation and characterization of the flow field in the condensing zone are made by computational fluid dynamics software which mainly includes the distribution rules of static pressure and velocity to explain the theoretical basis for optimum compact siro yarn properties in the practice of production. Fu et al [46] developed a pneumatic compact spinning system with an arc-shaped suction slot with lattice apron to determine additional twists inserted during condensing. Khurshid et al [47] investigated the influence of pneumatic compact spinning system by using Rieter® K-44 compact spinning with coarse, medium and fine linear densities of both ring siro and compact siro spun yarns hence to compare irregularity with respect to mass, IPI, hairiness and tensile properties between two types of siro yarn.…”
The compact spinning technique is one of the major improvements of classical ring spinning which has superior yarn structure and quality in terms of hairiness and strength. With a view to achieve, this paper reveals the significant correlation of differently aged lattice aprons of sussen compact spinning attachment with different yarn quality characteristics and fitting both simple and multiple linear regression equation. The 100% cotton compact yarns of 30's Ne are spun with differently aged lattice apron from the same cotton fibers, same roving and on the same spindles of the same ring frame with keeping the machine speed and doff length constant. The unevenness of mass variation U%, imperfection index (IPI), hairiness (H), countstrength-product (CSP), tenacity, elongation% of yarns are tested with quality control equipment and analyzed. Comparing with the new to 10-month aged lattices apron the evenness, strength, imperfections, and hairiness of produced yarns show decrement trends with an increment in elongation. The established multiple linear regression fitting line elicits the manufacturers to predict the quality of compact ring spun yarns.
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