Driven by the dual goals of carbon peaking, carbon neutrality, and green development policies, the fertilizer industry is facing a profound green transformation. “Zero emissions” and “low energy consumption” are no longer merely policy constraints, but intrinsic requirements for enterprises to enhance competitiveness and achieve sustainable development. Building a systematic environmental compliance system requires coordinated efforts in two aspects: comprehensive treatment of waste gas, wastewater, and waste residue, and energy-saving optimization of production processes.

Waste Gas Treatment: From “Harmlessness” to “Resource Utilization” During fertilizer production, processes such as raw material fermentation and drying easily generate irritating and harmful gases such as ammonia and hydrogen sulfide. Traditional open-loop treatment methods can no longer meet increasingly stringent emission standards, necessitating a systematic solution of “closed collection + tiered purification.”

Taking the organic fertilizer production line designed by Zhengzhou Huaqiang Heavy Industry as an example, by establishing a fully enclosed fermentation workshop, waste gas is collected centrally and first recovered through a condensation tower to achieve resource reuse; the remaining gas then enters a biofilter, where microbial metabolism degrades odorous substances such as hydrogen sulfide. This process not only reduces exhaust gas emission concentrations far below the “Odor Pollutant Emission Standard” (GB 14554-93), but also lowers nitrogen loss through ammonia recovery, achieving both environmental and economic benefits. Simultaneously, air curtains and negative pressure systems at workshop entrances and exits, combined with atomizing deodorization devices, significantly improve the factory area and surrounding environment.

Wastewater and Solid Waste: Recycling for “Zero Waste”

Wastewater from fertilizer production mainly originates from raw material washing, equipment cooling, and workshop rinsing. To achieve “zero emissions,” a graded treatment and recycling water resource management system needs to be established: suspended solids are removed through sedimentation and flotation, followed by biochemical treatment to degrade organic matter. The treated water can be used for raw material humidification, granulation humidification, or equipment cooling, forming an internal water cycle within the factory and significantly reducing the amount of fresh water required.

Solid waste can also be converted into resources. Screen residues and insufficiently strong particles generated during production can be crushed and reused in the granulation process; some fine powder can also be sold as a horticultural substrate or soil conditioner. This not only reduces the pressure of solid waste disposal but also improves the comprehensive utilization rate of raw materials and lowers production costs.

Low Energy Consumption Optimization: A Dual Approach of Technology and Management

Reducing energy consumption requires starting from the source—equipment selection and process design. In the granulation stage, using a rotary drum granulator equipped with a variable frequency control system allows for automatic speed adjustment based on material conditions, avoiding energy waste caused by over-engineering and saving over 30% more electricity than traditional fixed-speed equipment. For heat-sensitive materials, “room-temperature forming” processes such as roller pressing can be used, eliminating the drying stage and directly reducing heat consumption.

Furthermore, establishing an intelligent energy monitoring platform collects real-time data on electricity, water, and gas consumption at each stage. Analysis identifies energy efficiency bottlenecks, providing a basis for continuous improvement. Regular equipment maintenance and thermal system optimization are conducted, such as recovering waste heat for raw material preheating, further tapping into energy-saving potential.

Building a Long-Term Environmental Management System

Environmental compliance is not a one-time investment but a dynamic process requiring long-term commitment. Enterprises should establish internal environmental management systems, clarify responsibilities at each stage, and conduct regular emission testing and audits. Simultaneously, maintaining technical collaboration with equipment suppliers and leveraging their experience allows for rapid process optimization. For example, partnering with suppliers like Huaqiang Heavy Industry, which possess comprehensive solution capabilities, provides access to full-cycle services from engineering design and equipment integration to operational support, significantly reducing the technical risks and time costs of addressing environmental requirements independently.

Closed-Loop and Efficient Organic Fertilizer Production

Achieving the “zero emissions” and “low energy consumption” goals requires an integrated approach within the organic fertilizer manufacturing system. This begins with controlled aerobic fermentation, managed efficiently by equipment like a large wheel compost turning machine or a chain compost turning machine, within enclosed facilities to manage emissions. The cured compost then enters a dedicated organic fertilizer production line. The core stage of organic fertilizer production granulation offers several technology paths, each with different energy profiles.

For energy-efficient shaping, a traditional organic fertilizer disc granulation production line using an organic fertilizer disc granulation machine is common. To save space and process steps, a new type two in one organic fertilizer granulator that combines mixing and granulation can be effective. More complex organic fertilizer combined granulation production line setups may integrate multiple methods. The selection of granulation technology directly impacts the need for subsequent drying, a major energy consumer, and thus must be aligned with the overall environmental strategy of the organic fertilizer manufacturing operation.

Therefore, a truly sustainable organic fertilizer plant integrates emission control from the composting stage with energy-conscious equipment selection in the granulation and drying stages, creating a holistic production system that is both environmentally compliant and economically viable.

Conclusion: Environmental Compliance is the Cornerstone of High-Quality Development. Facing the era’s challenge of green manufacturing, fertilizer producers should deeply integrate environmental requirements into their entire production and operation process. Achieving “zero emissions” through systematic waste gas, wastewater, and waste residue treatment, and reducing energy consumption through energy-saving technologies and refined management, not only meets regulatory requirements and mitigates operational risks but also improves resource efficiency, cultivates a green brand image, and ultimately gains a long-term development advantage in the industry’s transformation. Environmental compliance has become an essential path for fertilizer companies to move from “compliant survival” to “green competitiveness.”

In compound fertilizer production, granulation technology is a key factor determining product quality, production efficiency, and overall cost. Currently, rotary granulation and roller granulation are the two mainstream technologies in the market, each with its own applicable scenarios and technological advantages. How can enterprises scientifically choose the right technology based on their own needs? The following analysis examines the technology from multiple dimensions, including technical characteristics, applicable conditions, and economic benefits.

Roller Granulation: A Sound Choice for Large-Scale Production

Roller granulation technology’s core advantages are “high pelletizing rate” and “large-scale production.” Its process principle involves using a rotating drum to thoroughly mix and roll the material and binder, gradually forming uniform particles. The pelletizing rate of this technology can typically reach over 95%, with a production capacity ranging from 1 to 20 tons/hour, making it particularly suitable for large-scale continuous production lines.

In terms of raw material adaptability, rotary granulation has good compatibility with various nitrogen, phosphorus, and potassium raw materials and can be used with common basic fertilizers such as urea, ammonium sulfate, and diammonium phosphate (DAP). The resulting granules have high strength, good sphericity, and excellent physical stability, making them suitable for long-term storage and long-distance transportation. Therefore, they are widely used in the large-scale production of NPK compound fertilizers and general-purpose compound fertilizers.

Taking Zhengzhou Huaqiang Heavy Industry’s rotary drum granulator as an example, its special rubber liner design enables automatic cleaning and removal of lumps and nodules, significantly reducing the problem of clumping and agglomeration, and lowering downtime maintenance frequency and manual cleaning costs. For large fertilizer companies pursuing stable mass production and high product standardization, rotary drum granulation remains the preferred solution due to its mature technology and reliable operation.
     

Roller Press Granulation: A New Path to Energy Saving and Flexibility

Roller press granulation technology highlights “room temperature molding” and “energy saving and consumption reduction.” This process directly presses powdered raw materials into shape through high-pressure extrusion by two rollers, eliminating the need for subsequent drying. Overall energy consumption can be reduced to about 60% of that of rotary drum granulation.

In terms of raw material processing, roller press granulation has no special requirements for material particle size and is particularly suitable for heat-sensitive raw materials and the addition of trace elements. The minimal temperature fluctuations in materials during production prevent the decomposition and loss of nutrients due to high temperatures, allowing for the precise incorporation of trace elements such as boron, iron, zinc, and copper. This makes it suitable for producing various specialized and functional compound fertilizers.

This technology also offers a production capacity flexibility of 1-20 tons/hour, but its relatively lower equipment investment and simpler process make it more popular with small and medium-sized fertilizer companies or manufacturers focusing on product customization. For example, a Malaysian customer chose Huaqiang Heavy Industry’s roller granulation production line, which was designed specifically for the local hot and humid climate, enabling rapid installation, commissioning, and stable operation, effectively meeting the regional market’s personalized needs for specialty fertilizers.
          

Key Considerations for Enterprise Selection

When choosing between these two technologies, companies should conduct a systematic evaluation from the following four dimensions:

Product Type and Raw Material Characteristics

If the main products are general-purpose compound fertilizers and large-scale standardized products, and the raw materials do not contain heat-sensitive components, roller granulation is more suitable. For producing specialized fertilizers containing heat-sensitive materials such as trace elements and humic acid, roller granulation better ensures the stability of active ingredients.

Capacity and Scale Requirements: Drum granulation is suitable for continuous, high-volume production with a high capacity ceiling and strong production line scalability; roller pressing, on the other hand, adapts to flexible production modes of multiple varieties and small batches, especially suitable for order-based and differentiated fertilizer products.

Energy Consumption and Overall Cost: Roller pressing eliminates the drying process, resulting in significant advantages in electricity and heat consumption, making it suitable for regions with high energy costs. While the initial investment for drum granulation may be higher, unit costs can still be controlled at a low level in ultra-large-scale production.

Maintenance and Operation: Drum granulation equipment requires regular cleaning and maintenance, but current automated cleaning technologies have significantly reduced the manual burden; roller pressing has a relatively simple mechanical structure and low maintenance frequency, but it places certain demands on roller wear, requiring careful material selection and maintenance.

Diverse Granulation Technologies for Fertilizer Production

This comparative analysis highlights the strategic choice between wet and dry granulation paths within fertilizer production machine technology. The rotary drum granulator represents the standard for large-scale, high-volume wet agglomeration in the npk fertilizer manufacturing process. In contrast, the roller press granulator production line operates on the principle of dry fertilizer granules compaction, where a fertilizer compactor applies high pressure, eliminating the need for drying. This method is a distinct and efficient pathway within the broader npk manufacturing process.

The selection of granulation equipment is a fundamental decision in designing fertilizer manufacturing plant equipment. While drum and roller press are primary for NPK, other technologies serve niche markets. For organic production, an organic fertilizer disc granulation production line offers gentle shaping. For small-scale or specialized pellet production, a flat die pelleting machine provides a compact extrusion solution. Thus, a comprehensive fertilizer equipment supplier must master this entire spectrum of technologies to provide truly customized solutions based on client-specific raw materials, capacity, and product goals.

Ultimately, there is no single “best” technology. The optimal choice is the one that aligns with the specific economic, agronomic, and operational parameters of the production facility, ensuring both product quality and long-term profitability.

Conclusion: In summary, drum granulation and roller pressing are not simple substitutes, but rather complementary technologies based on different product strategies and production conditions. For large enterprises producing general-purpose fertilizers, roller granulation is a solid and efficient cornerstone; for small and medium-sized enterprises focusing on specialty fertilizers, roller pressing offers an energy-saving and flexible growth path. In today’s era of green manufacturing and precision agriculture, scientific selection not only affects corporate profits but also impacts the final efficacy and sustainable competitiveness of fertilizer products. It is recommended that companies conduct pilot-scale trials before making decisions, combining their own raw materials, market conditions, and operational goals to make the most suitable technological investment.

In the production of organic fertilizers, bio-fertilizers, and organic-inorganic compound fertilizers, granulation is a crucial process that gives the product its commercial form, improves application convenience, and enhances market value. Among numerous granulation equipment, the disc granulator, with its classic structure, intuitive operation, reliable operation, and outstanding cost-effectiveness, has always occupied a core position in small and medium-sized fertilizer production lines. Huaqiang Heavy Industry, combining years of technological research and development with project practice, provides an in-depth analysis of the application advantages, precise operation points, and systematic capacity optimization strategies of the disc granulator.

Core Advantages: Why Choose a Disc Granulator?

The advantages of the disc granulator stem from its ingenious working principle: well-mixed powdered materials are continuously fed into an inclined rotating disc, where, under the combined action of gravity, centrifugal force, and friction between materials, they continuously roll, agglomerate, and grow, ultimately forming uniform granules.

High pelletizing rate and excellent granule quality: Under mature process control, the pelletizing rate can typically be consistently maintained above 80%. The produced granules have good roundness, smooth surface, and excellent product appearance.

Easy to operate and maintain: The equipment structure is relatively simple, the operating principle is intuitive, and the technical requirements for operators are moderate. There are few daily maintenance points, and maintenance costs are significantly lower than some more complex models.

Highly adaptable and flexible: Particularly suitable for small-to-medium batch, multi-variety production, with convenient product formula switching. Good compatibility with organic materials, microbial agents, trace elements, and other additives.

Excellent cost-effectiveness: Under the same capacity requirements, its equipment purchase cost and subsequent energy consumption are usually more economical, making it an ideal choice for startups and cooperatives.

Precise Operation: Mastering Three Core Parameters While the disc granulator is “easy to use,” mastering its “effective use” hinges on the precise and coordinated control of three key process parameters: disc inclination angle, rotation speed, and raw material moisture content.

Disc Inclination Angle (typically 35°-55°): The inclination angle directly affects the residence time and rolling trajectory of the material within the disc. If the tilt angle is too large, the particles will roll off before they have grown sufficiently, resulting in a smaller particle size; if the tilt angle is too small, the particles will remain in the disk for too long, potentially causing overgrowth or even clumping. Fine-tuning is necessary based on material characteristics and the target particle size.

Disc rotation speed (typically 20-40 r/min): The rotation speed determines the magnitude of the centrifugal force on the material. Too high a speed will cause the material to be thrown towards the edge of the disk, resulting in insufficient rolling, irregular particles, and excessive powder; too low a speed will result in insufficient material lifting height, inadequate rolling, slow pelleting, and a wide particle size distribution.

Raw material moisture content (typically 25%-45%): Moisture acts as a “binder” for pelleting. Too low a moisture content will make it difficult for particles to form, resulting in more powder; too high a moisture content will cause the material to easily clump together, forming large pellets or causing a paste-like substance in the disk. Moisture content needs to be adjusted in conjunction with the amount of binder (such as bentonite or lignin sulfonate).

To reduce operational complexity, Huaqiang Heavy Industry’s intelligent disc granulator integrates a sensor and PLC control system, enabling real-time monitoring and automatic adjustment of tilt angle and speed for more stable and efficient production.

III. Capacity Optimization: Achieving Dual Improvement in Efficiency and Quality

To fully realize the equipment’s potential, system optimization across the entire production process is necessary:

Raw Material Pretreatment is Fundamental: Ensure the material entering the granulator meets the required fineness (ideally 80 mesh or finer) and is absolutely uniformly mixed (mixing uniformity coefficient of variation CV < 5%). Uniform and fine powder is the core prerequisite for forming uniform granules.

Scientific Selection of Binders: Given the poor binding properties of pure organic raw materials, scientifically adding an appropriate amount of binder is key to improving granule strength (reducing breakage rate) and one-time pelletizing rate. The optimal type and addition ratio must be determined through experimentation based on the raw material composition.

Maintaining Optimal Equipment Condition: Regularly (e.g., every shift or daily) clean the inner wall of the disc and the scraper of any adhering material to prevent hardening of accumulated material that alters the disc’s internal contour and affects material rolling patterns. Check the scraper wear to ensure it effectively cleans the bottom of the disc.

Standardized Operations: For mature products, the optimal combination of tilt angle, rotation speed, and feed rate should be determined and solidified through testing to form a Standard Operating Procedure (SOP) to ensure consistency across different shifts.

Case Study: Significant Benefits of Optimization A large agricultural cooperative in China adopted a φ2.2-meter disc granulator and a complete optimization solution provided by Huaqiang Heavy Industry when producing organic-inorganic compound fertilizer. Through refined raw material crushing and mixing, precise control of granulation humidity, and strict regular cleaning and maintenance, the production line’s capacity steadily increased from the designed 5 tons/hour to 7 tons/hour without major equipment modifications, and the granule qualification rate (particle size range and strength) remained above 90% for a long time. This not only directly increased output value but also significantly reduced the unit product production cost and enhanced market competitiveness by reducing rework rate and energy consumption.

Conclusion: The Modern Value of Classic Equipment As a timeless classic piece of equipment, the disc granulator’s value continues to be renewed with the support of intelligent control and systematic process optimization. For the vast majority of small and medium-sized fertilizer production enterprises, a deep understanding of its working principle, mastery of the key parameters, and comprehensive production management will enable them to stably and efficiently produce high-quality fertilizer products with this “economical and practical” equipment, thus winning their own place in the market competition.

Positioning Disc Granulation within Integrated Manufacturing

The disc granulator is a key piece of professional fertilizer manufacturing equipment within specific production lines. Its primary role of disc granulator for shaping is often employed in an organic fertilizer production line or a bio organic fertilizer production line, where it gently forms spherical pellets from moist organic powders. However, its application is not universal. For the mainstream npk fertilizer production process, high-volume production is often achieved using a rotary drum granulator. Alternatively, a double roller press granulator is chosen for dry compaction granulation. The choice depends on the material’s characteristics and production goals.

A complete npk fertilizer production line typically begins with precise batching using a npk bulk blending machine and other fertilizer raw material processing machinery and equipment. If a wet granulation method similar to disc granulation is chosen for NPK, a larger-scale rotary drum is often used instead. Thus, a disc granulation production line is specifically advantageous for small-to-medium scale organic or compound fertilizer production where gentle agglomeration and flexibility are prioritized over extreme high capacity.

Therefore, understanding the strengths and ideal applications of the disc granulator allows manufacturers to strategically integrate it into a broader equipment portfolio, selecting the optimal granulation technology for each product type and scale within a diversified operation.

Scientific Maintenance Extends Lifespan, Meticulous Management Ensures Efficiency

In the organic fertilizer production process, the dryer is one of the key pieces of equipment determining the final moisture content, particle stability, and overall production capacity of the product. Operating under harsh conditions of high temperature, high humidity, and high dust levels for extended periods, scientific maintenance is not only fundamental to ensuring stable equipment operation but also a core management element for reducing failure rates, extending service life, and controlling production costs. With decades of industry experience and technological accumulation, Huaqiang Heavy Industry has developed a systematic dryer maintenance management system to help customers achieve efficient and economical operation throughout the entire equipment lifecycle.

Daily Inspection: Building the First Line of Defense for Preventive Maintenance

Effective maintenance begins with standardized daily inspections. Operators should complete the following key checks before starting the machine each day:

Cylinder and Liner Inspection: Observe the wear condition of the wear-resistant lining plates (usually lifting plates or special linings) on the inner wall of the drying drum. When the wear thickness at a single point exceeds 3 mm, replacement should be planned immediately. Otherwise, wet material is prone to sticking and accumulating on the bare plate, severely reducing heat exchange efficiency and potentially causing uneven heating of the cylinder.

Ventilation and Screen Inspection: Clean the screens and grids at the inlet and outlet to ensure no debris such as woven bag fragments, stones, or tangled fibers block the flow. Unobstructed ventilation paths are crucial for timely removal of evaporated moisture and maintaining the circulation of the drying medium.

Transmission System Lubrication: Check the oil level sight glasses of the main drive gear and support roller bearing housings to ensure the lubricating oil level is within the standard range. Use the specified type of high-temperature anti-wear lubricating oil and replenish it weekly to form an effective oil film in high-temperature environments, reducing gear meshing wear and bearing loss.

Regular Maintenance: The Core of Systematic Deep Maintenance

Based on daily inspections, a periodic deep maintenance plan must be established and strictly implemented.

Monthly Maintenance: Use an infrared thermometer to focus on checking the operating temperature of each support bearing and transmission bearing. If the bearing surface temperature consistently exceeds 80℃, the machine must be stopped immediately for inspection. Check for insufficient lubrication, bearing damage, or misalignment during installation to prevent bearing sintering due to overheating, which could lead to a major shutdown.

Quarterly Maintenance: After shutdown, thoroughly clean the inside of the dryer drum. During long-term operation, dust and low-melting-point semi-coke deposits will accumulate on the drum wall, forming a heat insulation layer. High-pressure water jet flushing combined with mechanical scraping should be used to remove the scale, restoring the heat transfer efficiency of the drum’s metal surface. This can significantly reduce fuel consumption.

Annual Overhaul: A comprehensive shutdown overhaul should be scheduled annually. Key points include: replacing all aging seals (such as kiln head and kiln tail seals) to prevent air and material leaks; inspecting and replacing worn conveyor belts or chain plates; calibrating temperature sensors, pressure sensors, and other monitoring instruments using standard instruments to ensure the accuracy of process parameter data acquisition and provide reliable data for automatic control.

III. Professional Support and Intelligent Upgrade: Advanced Maintenance System Guarantee

In addition to independent maintenance, leveraging the professional services of equipment suppliers can effectively improve maintenance levels. For example, Huaqiang Heavy Industry’s full lifecycle after-sales maintenance solution for its Ukrainian customers includes not only regular on-site inspections and fault diagnosis, but also optimization suggestions for drying process parameters based on local fuel characteristics and raw material moisture fluctuations. This service extends the trouble-free operating life of the customer’s dryer to over 8 years and reduces annual comprehensive maintenance costs by approximately 40%.

Furthermore, the introduction of predictive maintenance technology is the future direction. By installing vibration sensors and online oil monitoring devices in key areas and connecting to an IoT platform, real-time monitoring and big data analysis of equipment operating status can be achieved, providing early warnings of potential faults and upgrading the maintenance model from “regular prevention” to “precise prediction.”

Conclusion: Maintenance Creates Value Dryer maintenance is not simply “repairing when it breaks down,” but a systematic project spanning the entire service life of the equipment. It requires companies to establish standardized processes from daily inspections, weekly maintenance, monthly upkeep to annual repairs, and cultivate employees’ habits of standardized execution. Scientific maintenance management directly translates into less unplanned downtime, lower energy and material consumption, longer equipment service life, and more stable product quality. For organic fertilizer production enterprises, investing in the meticulous maintenance of equipment is investing in the core competitiveness and sustainable profitability of the production line.

Integrated Production: From Fermentation to Finished Granules

The well-maintained dryer is a critical component within a complete organic fertilizer manufacturing system. Its role is to process material from the preceding organic fertilizer fermentation process, which is often accelerated by equipment like a chain compost turning machine. Following drying, the core stage of organic fertilizer production granulation shapes the material into a marketable product. Several granulation technologies are available within an organic fertilizer production line. A traditional method is the organic fertilizer disc granulation production line, which forms spherical pellets. For higher capacity, a rotary drum granulator may be used.

The choice of granulator is diverse. For cylindrical pellets, a flat die pelleting machine is effective. For space and process efficiency, a new type two in one organic fertilizer granulator (or a new type organic fertilizer granulator) combines mixing and granulation. More complex setups, like an organic fertilizer combined granulation production line, integrate multiple methods. When the process incorporates specific microbial consortia, it becomes a specialized bio organic fertilizer production line. Ultimately, this integrated approach defines modern organic fertilizer manufacturing, transforming raw organic waste into a standardized, nutrient-rich agricultural input.

Therefore, each piece of equipment, from the compost turner to the dryer and the granulator, is a vital link in a synchronized chain. Professional maintenance of each unit ensures the reliability and efficiency of the entire system, maximizing the return on investment in organic fertilizer production.