In the context of energy and materials transformation, the high-value utilization of lignocellulosic waste has become a research hotspot. Oil palm empty fruit bunches (OPEFB), as a major byproduct of the oil palm industry, have great development potential due to their rich lignocellulosic components that can be converted into biofuels or cellulose fibers. However, the complex three-dimensional structure of lignocellulose, particularly the content and distribution of lignin, greatly limits its degradation efficiency. Therefore, pretreatment is a crucial step in unlocking its value. Various pretreatment methods exist for oil palm empty fruit bunches, encompassing biological, physical, chemical, and physicochemical approaches. Among these, chemical pretreatment, due to its stable delignification efficiency and wide applicability, has become the most commonly used technical route.  It mainly includes alkaline pretreatment, dilute acid pretreatment, and organic solvent delignification. Different methods have their own characteristics, and combinations of multiple methods can achieve efficient delignification.

Alkaline pretreatment is one of the most widely used methods in the chemical pretreatment of oil palm empty fruit bunches. Its core principle is to break the ester bonds between lignin and hemicellulose using alkaline reagents, promoting the depolymerization and dissolution of lignin, while simultaneously removing some hemicellulose. This exposes the cellulose structure and improves the accessibility for subsequent enzymatic hydrolysis. Commonly used alkaline reagents include sodium hydroxide and potassium hydroxide. Potassium hydroxide is particularly suitable because it aligns with the high potassium content of oil palm empty fruit bunches, enabling nutrient recycling. The advantages of this method are relatively mild reaction conditions, minimal damage to cellulose, and good preservation of the target product yield, making it suitable for large-scale application in biofuel production.

Dilute acid pretreatment, on the other hand, focuses on breaking down hemicellulose, indirectly achieving an auxiliary delignification effect. Using dilute acids such as sulfuric acid and hydrochloric acid under heating conditions, hemicellulose can be rapidly hydrolyzed to produce pentose sugars, disrupting the integrity of the lignocellulosic structure and loosening the bond between lignin and cellulose, facilitating subsequent separation. The outstanding features of this method are its fast reaction rate, significant improvement in raw material digestibility, and lower reagent costs, making it suitable for processes that prioritize the recovery of hemicellulose. However, it should be noted that dilute acids may cause corrosion to the equipment, and excessive acid can damage the cellulose structure; therefore, reaction conditions need to be strictly controlled.

Organic solvent delignification is a highly selective pretreatment method that uses organic solvents such as ethanol and acetone to selectively dissolve lignin under certain temperatures and pressures, achieving efficient separation of lignin from cellulose and hemicellulose. The advantages of this method include high delignification efficiency, the ability to recover high-purity lignin byproducts, and minimal damage to cellulose and hemicellulose, which is beneficial for the subsequent preparation of high-quality cellulose fibers or bio-based chemicals. However, the high cost of organic solvent recovery and the toxicity and flammability of some solvents limit its large-scale application, and it is currently more often used in the research and development of high-value-added products.

Single chemical pretreatment methods often have limitations; for example, alkaline pretreatment has limited effectiveness in removing hemicellulose, and dilute acid pretreatment can easily damage cellulose. Therefore, combining different chemical methods, or combining them with physical and biological methods, can achieve complementary advantages and significantly improve delignification efficiency. For example, removing hemicellulose with dilute acid first, followed by alkaline pretreatment to remove lignin, can significantly improve the subsequent enzymatic hydrolysis effect. In the future, by optimizing pretreatment process parameters and developing green and environmentally friendly chemical reagents, the chemical pretreatment technology of oil palm empty fruit bunches will develop towards efficiency, low cost, and sustainability, laying a solid foundation for its high-value utilization.

From Pretreatment to Pellet: The Fertilizer Production Pathway

Following effective chemical pretreatment, OPEFB becomes a valuable carbon-rich component for organic fertilizer. To be integrated into a commercial organic fertilizer manufacturing system, the processed fibers often require composting. This can be efficiently managed using a large wheel compost turning machine or a chain compost turning machine to aerate windrows, ensuring thorough biological stabilization. Once cured, this compost forms the base material for the granulation stage, a critical phase of organic fertilizer production granulation. The choice of granulation technology is diverse: for spherical granules, an organic fertilizer disc granulation production line is common, while an organic fertilizer combined granulation production line might integrate multiple shaping methods.

The selection of specific fertilizer raw material processing machinery and equipment depends on the desired final product form. For dense, cylindrical pellets, a flat die press pellet machine for sale offers an efficient extrusion solution. For operations seeking space and process efficiency, a new type two in one organic fertilizer granulator that combines mixing and granulation in a single unit can be highly effective. This integrated approach ensures that pretreated lignocellulosic materials like OPEFB are transformed into consistent, easy-to-handle fertilizer products with improved nutrient delivery and soil amendment properties.

This complete pathway—from chemical delignification and composting to precision granulation—demonstrates how agricultural byproducts can be systematically upgraded into standardized, high-value organic fertilizers, contributing to a circular economy in agriculture.

At the end of August 2025, Zhengzhou Huaqiang Heavy Industry Technology Co., Ltd.’s customized 8-ton/hour extrusion granulation production line for a Malaysian client completed full-process commissioning and officially entered the mass production stage. With its core advantages of high capacity, high precision, and low energy consumption, this production line perfectly adapts to local raw material characteristics and environmental standards. Its modular design and intelligent configuration have become a typical model for high-end extrusion granulation equipment exported overseas.

Production Line Core Configuration and Process Link

The entire production line follows a closed-loop process design of “pre-treatment – mixing – granulation – post-treatment – finished product packaging.” Each unit of equipment is precisely matched and works in synergy for high efficiency, achieving an automation level of over 90%.

Raw Material Pre-treatment and Mixing Unit

The raw material conveying system uses three belt conveyors of different specifications, respectively responsible for raw material transfer, intermediate material connection, and return material conveying. The conveyor belt width is adapted to the 8-ton/hour capacity requirement, ensuring smooth operation without material spillage, and improving conveying efficiency by 15% compared to conventional equipment.

The core mixing equipment uses two 1.2×3.0 meter twin-shaft horizontal mixers with counter-rotating blades, ensuring a mixing uniformity error of ≤3%. The equipment is equipped with a variable frequency speed control system, allowing for flexible speed adjustment based on raw material moisture content and proportions, ensuring the moisture content of the mixed materials is stably controlled within the optimal granulation range of 28%-32%.

The core granulation unit utilizes four 2.5-type double-roller extruders operating in parallel. Each machine has a capacity of 2.2 tons per hour, achieving a total designed capacity of 8 tons per hour when operating together. The rollers are made of high-chromium alloy, achieving a hardness of HRC60 or higher after quenching treatment, resulting in three times the wear resistance of ordinary materials and extending the service life to over 8000 hours.

The granulators employ a hydraulic pressure regulation system, allowing for precise control of the extrusion pressure within the range of 5-15 MPa, suitable for granulating various materials such as organic fertilizers and compound fertilizers. The roller surface features a customized serrated design, effectively enhancing material gripping force and maintaining a stable granulation rate above 92%. Particle size is uniformly controlled within 3-5mm, meeting customers’ standardized production requirements.

Post-processing and Environmental Protection Unit: The screening stage is equipped with one 1.8×6.0 meter double-layer drum screen. It employs a grading design; the upper screen separates large pieces of material, while the lower screen filters qualified particles. Unqualified material is directly returned to the mixer for regranulation via a return conveyor belt, achieving a material utilization rate of 98%.

The environmental protection system integrates a pulse-jet dust collector and exhaust gas treatment device. Through a negative pressure dust collection design, dust generated during production is collected and treated centrally, with dust emission concentration ≤10mg/m³, fully complying with local Malaysian environmental regulations. Equipment operating noise is controlled below 75dB, achieving green and low-carbon production.

Finished Product Storage and Packaging Unit:

The finished product silo has a capacity of 20 cubic meters and is equipped with a material level monitoring system to provide real-time feedback on material levels, preventing spills or shortages.

The packaging process utilizes a fully automated quantitative packaging machine. Packaging specifications can be flexibly adjusted within the range of 25-50 kg/bag, with a packaging error of ≤±0.2 kg and a packaging speed of 120 bags/hour, meeting the needs of large-scale shipments.

Core Technological Advantages of the Production Line:

Modular design is used throughout the entire process. Each equipment unit can be independently disassembled and maintained, significantly reducing downtime for maintenance and achieving an overall equipment uptime of over 95%.

An intelligent control system is adopted, integrating a PLC touchscreen operating interface. This allows for real-time monitoring of the operating parameters of each piece of equipment (speed, pressure, temperature, etc.), supports automatic fault alarms and data logging, facilitating remote management and process optimization for customers.

The overall layout of the production line is compact, requiring only 800 square meters of space, saving 20% ​​of space compared to conventional production lines with the same capacity. Simultaneously, optimized material conveying paths shorten transfer distances, and energy consumption is reduced by 12% compared to the industry average.

The successful commissioning of this 8-ton-per-hour extrusion granulation production line once again demonstrates Huaqiang Heavy Industry’s technological strength in the field of high-end fertilizer equipment manufacturing. In the future, the company will continue to focus on equipment performance upgrades and process optimization to provide global customers with more competitive customized production line solutions.

Comparative Granulation Technologies in Fertilizer Manufacturing

This Malaysian project highlights the efficacy of extrusion-based fertilizer compaction technology. The roller press granulator production line operates on the principle of dry fertilizer granules compaction, where the fertilizer compactor applies high pressure to form dense granules. This method is a key part of modern npk fertilizer manufacturing process and organic fertilizer manufacturing process when dealing with dry powders. In contrast, the npk manufacturing process often employs alternative technologies like the rotary drum granulator, which uses a wet agglomeration method with a liquid binder. For organic systems, a dedicated organic fertilizer disc granulation production line is common, where the disc granulator for shaping forms granules through a tumbling and layering action.

The choice of fertilizer production machine technology—be it a fertilizer compaction machine for dry compaction or a drum/disc for wet agglomeration—fundamentally shapes the entire organic fertilizer manufacturing system. Extrusion offers advantages in energy efficiency (no drying needed) and granule hardness, while rotary methods often provide higher capacity and spherical shape. The optimal selection depends on raw material properties, desired product characteristics, and overall production economics.

Therefore, a comprehensive fertilizer equipment supplier must master these diverse granulation technologies to provide truly customized solutions, matching the precise mechanical, chemical, and economic requirements of each client’s operation, whether for NPK or organic fertilizer production.

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