For manufacturing companies, equipment performance and cost control are crucial. Disc granulators excel in both areas, making them a powerful tool for enhancing competitiveness.

First, they offer exceptional energy efficiency. Compared to traditional granulation equipment, they consume less energy. Long-term use can save companies significant energy costs and effectively reduce production and operating costs. Second, disc granulators offer high production efficiency and enable continuous production. Depending on production needs, hourly output can range from several tons to tens of tons, meeting the production needs of companies of all sizes and helping them quickly complete production tasks.

Disc granulators offer even greater advantages in granulation quality. They produce highly uniform, strong, and resistant granules, ensuring high product quality for fertilizers, mineral powders, and chemical raw materials. Furthermore, they are easy to operate, requiring minimal training for operators to master their operation. This reduces production risks associated with complex operations. Maintenance is also relatively simple, further reducing management costs.

To maximize the performance of a windrow compost turner, a scientific and standardized operating process must be followed. The entire process of the windrow compost turner revolves around four key steps: raw material pretreatment, windrow accumulation, turning and fermentation, and determination of maturity.

Raw material pretreatment is fundamental. Collected organic materials must first be sorted to remove impurities such as metal and plastic. Livestock and poultry manure should be air-dried to a moisture content below 65%, and straw should be pulverized to 5-10 cm in length. The raw materials should then be mixed at a carbon-to-nitrogen ratio of 25-30:1. The carbon and nitrogen content can be adjusted by adding straw or manure, ultimately achieving a moisture content of 55%-60%. At this point, the material will clump when held and fall apart upon contact, achieving optimal fermentation conditions.
Next, the pre-treated raw materials are stacked into trapezoidal stacks at the fermentation site. These stacks are typically 3-5 meters wide at the base, 1.5-2.5 meters wide at the top, and 1-1.8 meters high. The stack length can be adjusted flexibly based on the site and production volume. A 1.5-2 meter passageway is left between the stacks to facilitate equipment access and ventilation.

Turning and tossing is a key step in fermentation. After starting the windrow compost turner, the depth of the tossing mechanism is adjusted according to the height of the stack, ensuring that the tossing teeth penetrate 10-20 cm into the bottom of the material. The initial fermentation lasts 1-3 days, with the first tossing occurring when the material temperature reaches 50-60°C. The high-temperature period lasts 4-10 days. When the temperature rises to 60-70°C, the stacks are tossed every 1-2 days to kill harmful bacteria. The cooling period lasts 11-20 days. When the temperature drops to 40-50°C, the stacks are tossed every 2-3 days to promote humus formation. The entire fermentation cycle lasts 15-25 days.

Finally, the material is judged by maturity. When the temperature is close to room temperature, the color is dark brown, the texture is loose, and there is no odor or earthy smell, it is considered mature and can be sent to the next stage for processing.

In the fertilizer production industry, different types of fertilizer production lines correspond to varying production requirements and process characteristics. Understanding common fertilizer production line types and key equipment configurations is crucial for companies to plan production and improve efficiency.

Currently, mainstream fertilizer production lines include organic fertilizer production lines, NPK fertilizer production lines, and bio-organic fertilizer production lines. Organic fertilizer production lines primarily use agricultural waste and livestock manure as raw materials, producing organic fertilizer through fermentation, crushing, and granulation. NPK fertilizer production lines focus on optimizing the ratio of nitrogen, phosphorus, and potassium to produce compound fertilizers. Bio-organic fertilizer production lines build on traditional organic fertilizer production by incorporating biological strains to enhance the bioactivity of the fertilizer.

While different production lines have different focuses on equipment configuration, they share common core equipment. The crushing stage typically requires a fertilizer crusher to ensure the raw material particle size meets subsequent processing requirements. The granulation stage utilizes fertilizer granulators, such as disc granulators and rotary drum granulators. The mixing stage relies on a fertilizer mixer to ensure uniform mixing of the raw materials. Furthermore, fertilizer conveyors, screening machines, dryers, and coolers are essential equipment, collectively forming the complete fertilizer production process.

When configuring equipment, companies should carefully select equipment specifications and models based on the production line’s capacity, raw material characteristics, and product requirements to ensure optimal compatibility across all stages and improve overall production efficiency.

As a long-term operating equipment in fertilizer production, BB fertilizer mixers require scientific daily maintenance to effectively reduce downtime, extend their service life, and ensure stable production. Maintenance should focus on the core components of the BB fertilizer mixer, with the mixing mechanism being the key. Regularly inspect the agitator shaft and blades for wear. Deformed or damaged blades should be replaced promptly to prevent poor mixing performance. Regular lubrication of the agitator shaft bearings is also crucial to reduce friction and minimize the risk of damage.

Maintenance of the drive system, including the motor and reducer, is also crucial. Regularly monitor the motor’s temperature and noise during operation. Any abnormal heating or noise should be promptly investigated to prevent motor burnout. Reducer lubrication should be regularly replaced to ensure transmission efficiency and avoid excessive wear due to insufficient lubrication.

Maintenance of the feed and discharge systems is equally critical. After each run, check the feed and discharge ports for residual material blockages and clean them promptly to ensure smooth material flow. Also, check the seal of the discharge valve to prevent material leakage that could cause waste or pollute the production environment.

In addition, after each production, the inside of the mixing drum needs to be thoroughly cleaned to avoid residual raw materials from clumping and to prevent contamination of new raw materials during the next production. With the help of the easy-to-clean design features of the BB fertilizer mixer, the cleaning work can be completed efficiently.