Determination of the Failure Susceptibility of a Flat Die Used in Biomass Pelletizing Machines by Means of FEA-Based Design Exploration

Çelik, H. Kürşat; Yılmaz, Hasan; Rennie, Allan; Cinar, Recep; Fırat, Mehmet Ziya

doi:10.1007/s11668-018-0497-2

Cited by 3 publications

(2 citation statements)

References 18 publications

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“…Another utility model is a circular die granulator with a vertical main shaft equipped with a double reduction machine which drives the main shaft and rotates (CN205517625U). As it was stated by Celik et al, the research related to the design of an optimum die by means of computer-aided engineering and structural optimization approaches is very limited [13]. For this design, parameters such as the force required for densification, the capacity, plugger pressure surface, diameter and hydraulic cylinder speed, densifier flow rate, hydraulic pump, and motor selection were considered.…”

Section: State Of the Artmentioning

confidence: 99%

“…On the other hand, Macko group optimized the strength and kinematics of the movement of each component with Solidworks ® software in a machine with a capacity of up to 100 kg/h [16]. Celik et al studied the compression ratio (CR) by using a finite-element analysis (FEA) based on design for sample in single-hole flat die parameters (geometry dimensions) against various compression pressure values [13]. Likewise,Šooš et al developed, designed, and tested a compacting press (with a protected patented) for the production of pressing biofuels of the optimal shape, almost circular shape [17].…”

Section: State Of the Artmentioning

confidence: 99%

See 1 more Smart Citation

Design Proposal of a Prototype for Sawdust Pellet Manufacturing through Simulation

Paredes-Rojas

Miguel

Vela

et al. 2020

Advances in Materials Science and Engineering

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Mexican industry generates tons of organic wastes that are not used and cause social, environmental, and health problems. The main organic residue which is generated during wood production is the sawdust (biomass). In order to reduce the problems generated by its waste, a prototype to manufacture biofuel pellets was designed by considering a flat die pelletizing machine according to the standard EN 14961-2. The machine design consists of stainless steel 304 and carbon steel to produce pellets of 6 mm and 30 mm in diameter and length, respectively, at 50–100 rpm. The matrix types proposed were radial, spiral, and hexagonal. In order to be constructed quickly, the design is standardized. Results from finite-element analysis indicate that it is possible to manufacture pellets from 50 to 1000 PSI (344.7 kPa to 6894.7 kPa) with this design complying with the standard.

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Section: State Of the Artmentioning

confidence: 99%

Section: State Of the Artmentioning

confidence: 99%

Design Proposal of a Prototype for Sawdust Pellet Manufacturing through Simulation

Paredes-Rojas

Miguel

Vela

et al. 2020

Advances in Materials Science and Engineering

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A nonlinear elasto-plastic bond model for the discrete element modeling of woody biomass particles

et al. 2021

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Study on Flat Die Wear Characteristics in Flat Die Pelletizing with Different Material Ratios Based on DEM-FEM

Gao,

Dong,

Sun

2024

Agriculture

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Wear can occur in flat die pelletizers, often reducing service life. This study explores the issue of die hole wear in the pelletizing process of a standard Total Mixed Ration (TMR) feed. The selected TMR formulation comprises varying proportions of corn, alfalfa hay, and quinoa. A coupled DEM-FEM analysis was used to examine stress–strain conditions in various die hole regions at different material ratios, predict the fatigue life of flat die materials in the pelletizing process, and validate the accuracy of investigating flat die wear through friction wear tests. It was found that the entrance of the die hole experiences the most severe conditions in terms of equivalent stress and elastic strain. The fatigue life is shortest at the entrance, with a maximum equivalent stress of 42.8 MPa, a maximum equivalent elastic strain of 2.5 × 10−3, and a minimum fatigue life stress cycle of 5.0 × 105. In contrast, the equivalent stress and equivalent elastic strain at the middle and upper parts of the die hole are minimal, with an equivalent stress of 4.8 MPa and a minimum equivalent elastic strain of 2.8 × 10−4. Material wear tests revealed that the most severe wear on the flat die specimen occurred when the ratio of corn, alfalfa hay, and quinoa straw was 7:2:1, consistent with the findings from the DEM-FEM coupling method. The pelleting process, arising from the contact between the material and metal, encompasses adhesive wear, abrasive wear, and fatigue wear.

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Determination of the Failure Susceptibility of a Flat Die Used in Biomass Pelletizing Machines by Means of FEA-Based Design Exploration

Cited by 3 publications

References 18 publications

Design Proposal of a Prototype for Sawdust Pellet Manufacturing through Simulation

Design Proposal of a Prototype for Sawdust Pellet Manufacturing through Simulation

A nonlinear elasto-plastic bond model for the discrete element modeling of woody biomass particles

Study on Flat Die Wear Characteristics in Flat Die Pelletizing with Different Material Ratios Based on DEM-FEM

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