solutions

Table of Content 1. Introduction to Aqua-feed Production Line 2. Aqua-feed Processing Stages 3. Our Advantages 4. FAQ  1. Introduction to Aqua-feed Production Line 1.1 Product Categories Aqua-feed processing covers three major categories: Freshwater fish feed (e.g., four major Chinese carp species) Marine fish feed (e.g., grouper, sea bass) Crustacean feed (e.g., shrimp, crabs) 1.2 Key Process Characteristics Premium raw materials: High-protein biological ingredients (fishmeal, shrimp shell powder), superior fat sources, low-fiber formulations. Precision processing: Ultra-fine grinding (80-120 mesh vs. 40-60 mesh for livestock feed). Nutrient preservation: Low-temperature conditioning, vacuum coating to retain heat-sensitive nutrients. Advanced equipment: Dual-shaft differential conditioners, extrusion systems for high-fat (6-12%) and high-protein (28-45%) formulations. 1.3 Technical Requirements Precise temperature control, corrosion-resistant materials, and intelligent batching systems. Full-process quality control from raw material pretreatment to post-conditioning. 2. Aqua-feed Processing Stages 2.1 Core Solutions Project planning: Factory layout design based on raw material properties and product positioning. Process design: Modular integration of extrusion-drying-post-conditioning processes. Equipment matrix: Twin/single-screw extruders (1-20T/h) + micro-extrusion systems for fry feed. Smart control: Graded configurations from manual batching to DCS automation. Technical services: EPC turnkey projects, commissioning, and continuous process optimization. 2.2 Key Equipment & Features Extrusion systems: Floating feed twin-screw extruders (1-20T/h) Sinking/slow-sinking feed single-screw extruders (1-15T/h). Micro-extruders for fry feed (particle size: 0.5-1.2mm). 2.3 Process advantages Product range: Carp feed, marine fish extruded feed, shrimp/crab specialty feed, fry starter feed. Density control: Adjustable expansion rate (30-60%), precise density regulation (300-600g/L). AI integration: Raw material recognition, self-learning extrusion parameters, energy optimization. 2.4 Aqua-feed Processing Sections 2.4.1 Material Receiving  Closed unloading sheds with hydraulic tipping and high-suction dust removal. Dual indoor feeding ports (granular and powdered materials). Large closed feeding pits with automatic dust suppression.    2.4.2 Grinding Two grinding bins (20m³ capacity), equipped with iron-removal feeders and noise-reduction systems. Iron-removal feeder: Shields grinder components (screens, hammers), minimizing wear. Fan silencers: Reduce operational noise. Pulse filters + sealed screw conveyors: Block air leaks, boost efficiency, cut costs. Quality Control Pipeline sampler: In-process checks and control room sampling. Flexibility Pneumatic valves: Switch bins/grinders for flexible workflows. Level sensors: Signal grinding completion to operators. 2.4.3 Batching & Mixing 10-12 batching bins (total 120m³), designed for complex formulations. Dual weighing systems for speed and accuracy. Hard-gear reducers, double-layer scrapers, and pulse dust collectors to prevent blockages and dust leakage. 2.4.4 Ultra-fine Grinding & Secondary Mixing Screenless ultra-fine grinders (40-200 mesh adjustable). Air conveying with cyclone separators and pulse filters for environmental compliance. Secondary mixing for sensitive additives. 2.4.5 Extrusion& Drying Section       (1)Key Features:       Core production stage with two stainless steel pre-extrusion bins (for standard and small-sized pellets), equipped with rotary dischargers to prevent cross-contamination.     Twin-screw extruders (preferred for formula flexibility and high throughput): Integrated components: Frequency-controlled screw feeder, dual-speed differential conditioner, and extruder unit. Automated control system with touchscreen interface for real-time parameter adjustment (feed rate, temperature, steam pressure) and one-touch preset formulas.     (2)Optional upgrades:     Density control module for semi-sinking/sinking feeds     Emission-free dust/exhaust systems to eliminate workplace pollution.     Horizontal dryers with multi-stage temperature zoning (steam or gas-fired options) for energy-efficient drying.     Customizable screens (nylon, stainless steel perforated/wire mesh) tailored to material properties.     (3)Post-Processing:              Extruded and dried materials advance to the oil coating and cooling stages for final preparation. 2.4.6 Cooling, Screening & Packaging Counterflow coolers to prevent condensation and mildew. High-efficiency vibrating screens for impurity removal. Automated packaging systems with robotic palletizing to reduce labor costs. 3. Our Advantages Leading-edge core equipment: Internationally advanced extrusion and drying systems. 30+ years of expertise: Experienced engineering team in feed plant design. Smart manufacturing: AI-driven process optimization and energy management. Full-service support: Turnkey solutions from planning to post-installation optimization.   4. FAQ 1. Services offered?Turnkey solutions including plant planning, equipment supply, installation, and commissioning.2.Single-screw vs. twin-screw extruder?Depends on formula, product type, and budget. Contact sales for tailored advice.3.Installation process?Detailed installation drawings + on-site engineer guidance.4.Delivery time?90-120 days (project-dependent).5. Competitive edge?Advanced equipment, 30+ years of expertise, and smart manufacturing capabilities.6.Packaging standards?Steel pallets or export-grade wooden crates.7.Buyer preparations?Civil works, utilities (water, electricity, gas), and site readiness.8.Additional equipment needed?Transformer, weighbridge, boiler, air compressor, oil tanks, forklifts, etc.

Table of Contents 1. Introduction to Poultry & livestock feed production line 2. Processing Technology Overview 3. EXISTING PROJECT AND INSTALLATION 4. Q&A PART 1 Introduction to Poultry & livestock feed production line.      Professional Feed Processing Equipment Enables Customizable Poultry (Chickens/Ducks), Swine, and Ruminant (Cattle/Sheep/Goats) Feed Production to Meet Diverse Farming Demands. PART 2  Processing Technology Overview      Modern poultry feed manufacturing integrates modular systems for grinding, mixing, thermal conditioning,pelleting, and packaging. Precision-controlled workflows ensure customized nutrition profiles  (starter/grower/layer) while maintaining >98% formula accuracy. Our ISO-certified lines achieve 1-20t/h throughput with

Contents Introduction to Digital Intelligence Solution Core Digital Intelligence Modules Key Equipment & Project Showcase FAQ 1. Introduction to Digital Intelligence Solution-IoT-Driven Transformation for Feed Production Management Traditional feed mills rely on limited data from control rooms, lacking deep analytics. Manual inspections detect visible faults (e.g., material leaks) but fail to monitor equipment 24/7 or analyze trends. 1.1 IoT System Advantages: (1)Smart Equipment Management: Predictive maintenance reduces unplanned downtime by 42%, cuts O&M costs by 35%, and extends equipment lifespan by 15%. (2)Optimized Production Efficiency: Dynamic adjustment of parameters (e.g., grinding size, pelletizing temperature) increases product qualification rate to 99.6% and reduces energy consumption by 8.7% per ton. (3)Precise Energy Control: Peak/off-peak electricity visualization and smart scheduling save 870,000 kWh/year, reduce steam consumption by 13%, and deliver annual energy savings of ¥1.6 million.  1.2 Features: ² Real-time multi-terminal monitoring (phone/PC/TV) for data reports, energy curves, and alerts (e.g., motor overload, bearing temperature). ² Automated generation of equipment utilization, production analysis, and standardized reports (99.98% data accuracy). ² Edge-to-cloud architecture with millisecond-level data collection via industrial IoT gateways. 1.3 Key Modules: Ø Current, temperature, and vibration sensors for fault prevention (e.g., motor short circuits). Ø Cooling system monitoring to prevent condensation-induced spoilage. Ø Visual recognition for non-communicative meters (e.g., moisture detection).   2. Core Digital Intelligence Modules Host Equipment IoT System:Energy efficiency management, real-time status monitoring, anomaly alerts, and production analysis.                                                                                                                                                                                                     Energy Management A                                                                                                                                                                                                      Energy Management B Daily energy consumption distribution analysis The daily energy consumption of each equipment is automatically read and calculated Equipment efficiency management Real-time monitoring of the power-on status of the device  Get real-time visibility into the monthly uptime rate of each device Device status management The 24-hour graph makes it easy to see the status of the device. At the same time, there is also historical data, which can be the historical data of the previous month and the historical data of the previous year.  Stand-alone graph, which can reflect: 1. Time and efficiency of switching formulas; 2. Whether the host is idling; 3. Whether there is equipment idle; 4. Whether it is inefficient to start; 5. Compare the production efficiency of the host Equipment anomaly Management It can monitor the motor of the equipment to prevent the motor from burning out due to short circuit between turns When the current of the section is high or idling for more than a certain time, the site will issue an early warning, and when the site is not processed, the early warning will enter the abnormal report. On-site warning                                              Capacity reports     Including the report of power consumption per ton of host equipment or production line, including the hourly output of host equipment or production line, etc., including the steam consumption per ton of host equipment or production line, etc Pulverizer control module  Cooler temperature differential control module Radar real-time material meter module The depth of materials in silos, raw material bulk silos, finished product bulk silos, batching silos, crushing silos, and finished product silos is collected  Communication module   for steam, air compressor, water, flow bulk scales, oil scales, etc. (optional)There is a communication module for steam, air pressure, water, flow bulk scale, oil scale, and weighbridge, which can be collected automatically Visual recognition module of the instrument.                                                                                                                                               On-line moisture detection module Some instruments cannot be collected by communication, but can be collected by vision                                                        Detection of cooling moisture and finished product moisture                          3. Application Cases Case 1:Reduced idle time from 360 hours (May) to 85 hours/month, saving $1,857/month in electricity (based on exchange rate: 1 USD ≈ 7 CNY). Case 2:Cut auxiliary equipment runtime by 50%, avoiding energy waste. Case 3:Reduced unplanned downtime from 30 to 2-3 hours/month via predictive maintenance. Benefits: Before using the module, a feed mill in Putian had an unplanned shutdown of about 30 hours per month, and now the unplanned downtime per month is about 2-3 hours The app for preventive maintenance will have a QR code on site, and the mechanic needs to scan it every day for preventive maintenance Case 4:Improved pelletizer and extruder efficiency by 4%, saving $1,428+/month in costs. Host real-time parameters, load rate Health of auxiliary equipment OEE Real-time underload warning the number of shutdwons analysis Time of the variety conversion Production Output,Tonne of power Consumption Report Case 5:Benefits: Batch 2 of the mixer, through the efforts of the organization, from 9P/H to 10P/H, the organizational efficiency has been improved a lot. Improve personnel team efficiency Batch of the mixer Comparison of teams Startup Curve Comparison Chart   Case 6:Shifted 15% peak electricity usage to off-peak hours, saving $428/month in electricity fees. 3.Project installation site 4.FAQ Q1: What does the system do? A: Digitizes equipment operations for data-driven production optimization, energy savings, and efficiency. Q2: Compatibility with existing equipment? A: Non-invasive installation via sensors and software; no hardware modifications required. Q3: Delivery timeline? A: 45–60 days, depending on project scale. Q4: Installation process? A: Modular hardware; requires basic electrical skills. Q5: After-sales service? A: Lifetime support with 3 years free service; minimal annual fees thereafter.

Table of Contents 1.Classification and Detailed Explanation of Control Methods 2.How to Configure Full Computer Control 3.How to choose a PLC brand 1. Classification and Detailed Explanation of Control Methods 1.1 Principles for Classifying Control Methods: Ø Cost Ø Automation level Ø Inclusion of PLC, computer, or touch screen 1.2 Control Method Classification (1)Mimic Panel Control:A purely button-based control mode. Advantages: Low cost, low automation level.    Typical Usage: Simple processes, such as basic silo or grinding processes.   (2)Computerized Recipe + Mimic Panel Control: Combines button control with computer-operated recipe control for the mixing section. Advantages: Economical and practical, offering more flexibility in the control of batching while maintaining simplicity.    Typical Usage: Common in feed mills with moderate complexity, balancing cost and functionality.   (3)Fully Computerized Control:All equipment can be controlled via a computer. Advantages: High automation level, better data tracking, and centralized control.    Typical Usage: High-end systems where precision and full automation are required, such as large-scale production lines.   (4)Computerized Recipe + Mimic Panel Control + Standalone Touchscreen: A combination of button-based control, computer recipe operation, and some complex machinery controlled via touchscreen. Advantages: Cost-effective, offering a blend of practical control and some automated functions where needed.    Typical Usage: Common in systems that need some automation for specific machines but where full automation is not necessary.   ² Mimic Panel Control Simple process with equipment that only requires sequential start/stop, such as silo process, simple feeding + grinding process, raw material extrusion process (extruder controlled by button-type on-site control box), and pelleting process (pellet mill controlled by button-type on-site control box).   PIC 1:A simple silo process can meet control requirements using a mimic panel system—cost-effective and practical, with intuitive button-based operation. PIC 2:A single grinding line with minimal equipment can meet control requirements using simple buttons and knobs. PIC 3:Raw material extrusion involves more complex equipment, but from an economic perspective, a mimic panel still effectively meets control requirements. PIC 4:For livestock and poultry feed pelleting, feed rate is controlled by knobs and valves are adjusted manually—resulting in low automation and low cost. PIC 1  PIC 2  PIC 3  PIC 4 ² Computerized Recipe + Mimic Panel Control The relatively simple livestock and poultry feed process typically includes feeding, grinding, batching, mixing, and pelleting/packaging. The pellet mill is controlled by a button-based control box on-site, while the batching section requires computer operation. PIC 1:The complex batching section is controlled by a combination of computer and PLC, offering an economical and practical solution that meets automation requirements! PIC 2:Pictures from the scene ² Fully Computerized Control Applicable to any form of production process! Operational efficiency is greatly improved, leading to increased effective working hours and higher output. The automatically recorded production data, transmitted paperlessly, provides production managers with accurate and real-time information. PIC:Any process can be fully computerized ² Computerized Recipe + Mimic Panel Control + Standalone Touchscreen Suitable for aquaculture processes, this product is designed with the customer’s economic considerations in mind! Aquaculture feed processes are complex, involving batching, and may include pellet mills, extruders, oil spraying, vacuum spraying, and other equipment with complex logical relationships that require PLC control for individual machines.   Summary: Control mode Application Occasion Feature Mimic Panel Control The process is simple, no ingredients, no complex stand-alone machine Practical, affordable and convenient Computerized Recipe + Mimic Panel Control With 2~3 lines of batching livestock and poultry feed engineering Higher degree of automation and more convenient Fully Computerized Control Livestock and poultry feed, aquatic feed process with more production lines High degree of automation and convenience Computerized Recipe + Mimic Panel Control + Standalone Touchscreen Aquatic material process, including some complex stand-alone machines (aquatic extruder, vacuum spraying, grease spraying, etc.) Affordable, but not practical   2.How to Configure Full Computer Control Control point Control mode Feature Silo Section The box spray screen button control at the warehouse entry site, and the computer control of the main workshop of the warehouse and the warehouse reversal part Easy to operate and practical Feeding Port   1. Telephone + sound and light alarm box 2. Telephone + sound and light alarm box + LED Practical and affordable Minor Ingredient Addition On-site sound and light alarm box + LED + touch screen It can be combined and practical pellet mills, extruders Button field box semi-automatic touch screen fully automatic control mode The degree of automation increases Grease spraying, vacuum spraying, molasses addition, etc It is recommended to control in the central control room, and there is no need for a field box Fully automated control, no more wasted labor costs Pulse Dust Removal Computer-controlled or on-site control by pulse controller It is recommended to control the pulse control, which is low cost, easy to operate and maintain, and simple to maintain 3.How to Select PLC Brands Brand/Model        Applicable Scenarios *Siemens S7-300*    Full computer control (WinCC configuration) Mitsubishi Q Series   Full computer or complex process control Mitsubishi FX Series  Cost-effective non-full computer control Weintek HMI        Cost-effective human-machine interface At present, the common control software of the company's full computer control mode includes Siemens control system (Siemens S7-300 PLC + WinCC configuration software), Mitsubishi control system (Mitsubishi Q series PLC + WinCC configuration software) Non-fully computerized control mode adopts single batching system (Mitsubishi FX series PLC+ WinCC configuration software). According to customer needs, we can customize the design of common configuration software and PLC in the industry. Classification of Control Methods PLC PLC configuration software (touch screen, etc.) remarks Full Computer Control Siemens 300 Siemens WinCC   Mitsubishi Q Siemens WinCC 　 Computer Batching + Analog Panel Control Mitsubishi FX Siemens WinCC   Complex stand-alone Mitsubishi FX

Table Of Contents 01 Introduction of premix production line 02 Introduction to the premix process 03 Project site 04 FAQ Part 1  Introduction to Feed Premix and Processing Technology Feed premix is a core ingredient composed of precisely proportioned functional additives (including vitamins, trace minerals, amino acids, enzymes) and carriers. It enhances the nutritional balance and utilization efficiency of feed. The processing technology adheres to scientific formulation and high-efficiency mixing principles to ensure the stability of active ingredients.   The production involves three key stages:   (1) Raw Material Pretreatment: Carriers (e.g., cornmeal, bran) undergo impurity removal and drying to ensure moisture content ≤10%;   (2) Stepwise Dilution and Mixing: Ingredients are added in the order of carrier → macro-components → micro-components, using a double-shaft paddle mixer to achieve a mixing uniformity CV ≤5%;   (3) Packaging and Storage: Finished products are packaged with double-layer moisture-proof materials and stored at 15-25°C.   This technology ensures precise loading and uniform distribution of micro-components, effectively minimizing nutrient loss. The premix meets the nutritional needs of livestock and poultry across growth stages. When integrated with automated batching systems, it improves complete feed production efficiency by over 30%. The entire process strictly complies with the HACCP system, guaranteeing product safety and stability.   Part 2 Common premix processing technology 500kg/batch Manual batching premix (1) 2.1 Process Description This process employs manual batching: materials are weighed, lifted to the feeding platform via an electric hoist, and manually fed into the mixer for blending and packaging. The mixer utilizes single-shaft or double-shaft stainless steel designs, ensuring high mixing precision, corrosion resistance, and excellent sealing performance. The process features a relatively simple workflow, compact footprint, and lower overall investment. Limitations: Higher labor costs compared to automated systems. To enhance flexibility, modular design can be adopted: integrate equipment, platforms, and steel structures into container-sized modules. Users only require simple on-site installation for immediate operation. 500kg/batch manual batching premix (2)   2.2 Process Description This process utilizes manual batching: materials are weighed, elevated to the feeding platform via a bucket elevator, and manually loaded into the mixer for blending and packaging. The mixer employs single-shaft or double-shaft stainless steel designs, delivering high mixing precision, corrosion resistance, and superior sealing performance. The process offers a simplified workflow, compact footprint, and slightly higher total investment compared to Option 1 (due to the bucket elevator replacing the electric hoist), while providing improved stability and operational convenience. Limitations: Relatively higher labor costs. To optimize flexibility, a modular design can be implemented: integrate equipment, platforms, and steel structures into container-sized modules. Users only need to perform simple on-site installation for immediate operation. 500 kg/batch automatic batching premix(3) 2.3 Process Overview This process employs automated batching: carrier materials are elevated via a bucket elevator for cleaning, then conveyed to batching silos for precision dosing. Minor components are manually fed into the mixer. The system utilizes single-shaft or double-shaft stainless steel mixers, ensuring high mixing accuracy, corrosion resistance, and airtight sealing. Mixed products are packaged via stainless steel packing scales, integrated with a pulse dust removal system. (1) Advantages ØHigh automation level, significantly reducing labor costs. ØExceptional dosing accuracy. (2) Considerations ØBatching silos increase structural load, requiring reinforced steel frameworks. ØHigher initial investment in steel structures, moderately larger footprint, and moderately higher total budget. ØIdeal for clients prioritizing automation, operating in high labor-cost regions, and accepting elevated equipment investments. Part 3  Premix production line site The feeding port is equipped with stainless steel pulse dust collector and cyclone Initial cleaning and installation platform Automatic batching system Stainless steel batching hopper and small material feeding station Stainless steel mixer Stainless steel packaging scale Part 4  Q&A Q1. What services do you provide? A1: We offer turnkey solutions including complete plant planning, equipment budgeting, process design, and project installation/commissioning services. Q2. How is installation conducted? A2: We provide full installation drawings and dispatch guidance engineers to supervise on-site installation. Q3. What is the delivery timeline? A3: Delivery typically takes 90-120 days, depending on project scale. Q4. What is the required footprint? Can it be installed in a warehouse? A4: The footprint varies with design specifications, but most systems can be installed in standard warehouses. Q5. How is packaging handled? A5: Equipment is secured on steel pallets and packed in export-grade wooden crates. Q6. What preparations are required from the buyer? A6: Complete civil engineering construction, ensure utilities (water, electricity, gas) are operational, and prepare the site for equipment installation. Q7. What additional supporting equipment is needed? A7: Auxiliary systems include transformers, weighbridges, boilers, air compressors, fuel storage tanks, and forklifts.

Table of Contents  1. Small-Scale Aquatic Feed Production Line Overview   2. Processing Technology   3. Project Site Showcase   4. FAQ   Part 1  Small-Scale Aquatic Feed Production Line Overview Small-Scale Aquatic Feed Production Line Solution (Hourly Output: 500 kg – 2 tons) Designed for startups and farms with self-production needs, this modular solution prioritizes cost efficiency and customization. 1.1 Key advantages over large-scale industrial feed mills include:   (1) Cost-Effective Configuration Semi-automated design reduces initial investment. Critical sections retain manual interfaces (e.g., manual batching), and economical fine-grinding equipment replaces costly super-micro grinding systems.   (2) Flexible Process Design   Scalable output from 500 kg/h (base module) to 2 tons/h. Compatible with both extrusion and pelletizing modes to meet diverse feed form requirements for aquatic species.   (3) Compact Layout Flat equipment arrangement minimizes workshop height (

Table of Contents 1. Introduction to Small-Scale Poultry & Livestock Line 2. Processing Technology Overview 3. Key Equipment and Project Site Showcase 4. Q&A 1. Introduction to Small-Scale Poultry & Livestock Line Modular Feed Production Solution (Hourly Output: 500 kg – 5 Tons) Designed for startups and farms, this solution emphasizes low investment and flexible configurations. 1.1 Key advantages include: Modular Capacity: Scalable output from 500 kg/h to 5 T/H. Compact Steel Workshop: Reduces infrastructure costs by 30%. Integrated Layout: Full production within 500 m². Versatile Product Range: Produces pellets for pigs, poultry, ducks, fish, cattle, and sheep. 1.2 Global Adaptability: ✓ Corrosion-resistant design for Southeast Asia’s humid climate. ✓ Backup power solutions for Africa’s unstable grids. ✓ Flexible raw material processing for South America’s diverse inputs. Full-Cycle Services: Plant planning, formula optimization, installation, and commissioning to ensure consistent quality, market-ready capacity, and future scalability. 1.3  Applications: Ø Cost-effective feed production for family farms. Ø Regional distributors transitioning to in-house manufacturing. Ø Satellite factories for large breeding groups. Ø Customized specialty feed production. 2. Processing Technology Overview (1)1-2 T/H Line: Granular materials are conveyed via screw conveyor to the grinder, then mixed. Powdered materials enter the mixer directly. The blended mixture is pelletized using single/double-layer conditioners, cooled, screened, and manually packed. Includes a control cabinet; auxiliary equipment (boiler, air compressor) can be customized.   (2)02-3 T/H Line: Granular materials are first crushed and then conveyed via a bucket elevator (upgraded for reduced footprint and increased lifting height). Powdered materials are manually fed directly. A buffer mixing silo facilitates easier feeding before materials enter the mixer for homogenization. The blended mixture is lifted to a pelletizing buffer silo and processed through a pellet mill equipped with single or double-layer conditioners. Post-pelletizing, the product undergoes cooling and screening via an integrated unit. An optional semi-automatic bagging scale enhances packaging efficiency. Standard Configuration: Control cabinet Auxiliary equipment (boiler, air compressor) can be self-procured or added as optional. This design optimizes space, efficiency, and flexibility for mid-scale feed production. (3)2-5 T/H Line: Granular materials are crushed and elevated via space-saving bucket elevators, with direct manual feeding for powders. Features a pre-mixing bin for streamlined feeding and a dual-shaft paddle mixer ensuring thorough blending. Processed materials move to pre-pelleting bins, with optional single/double-layer conditioners. Pellets undergo cooling, screening, and automated electronic packaging. Includes control cabinet; boilers/compressors optional. Compact design supports efficient mid-scale feed production. (4)3-7 T/H Line The 3-7 ton production line shares the same fundamental process configuration as the 5-ton production line, offering enhanced production capacity and expanded workshop space. (2)3-7 tons hard pellet feed production line(Automatic batching) 3-7 Ton Automated Batching Line: Implements a "batch-then-grind" process. Four batching bins (expandable to 6-8) handle primary materials, reducing labor and boosting precision. Batched materials are ground, while minor powdered additives are manually fed into the dual-shaft paddle mixer. Mixed materials proceed to pelleting (single/double-layer conditioners optional), followed by cooling, screening, and efficient automated packaging via electronic weighers. Includes control cabinet with computerized batching; boilers/compressors optional. A semi-automated entry-level setup for commercial feed mills, enabling continuous high-volume production with moderately elevated investment. 3. Key Equipment and Project Site Showcase 3.1 Core Equipment: Hammer Mill: High-speed grinding with tungsten carbide hammers. Mixer: Ribbon or twin-shaft paddle designs for minimal residue. Pellet Mill: Dual-motor belt drive, adaptable to various raw materials. Control System: Compliant with national 3C standards, upgradeable to computerized batching. 3.2 Project Photos:   3.3 Packing & Logistics: Steel pallets or export-grade wooden crates. 4. Q&A Q1: What services do you offer? A1: Turnkey solutions including plant design, equipment procurement, process engineering, installation, and commissioning. Q2: How is installation managed? A2: We provide detailed installation drawings and on-site engineer guidance. Q3: What is the delivery time? A3: Typically 90–120 days, depending on project scale. Q4: Can the line be installed in a warehouse? A4: Yes. The compact design allows installation in warehouses with minimal space requirements. Q5: How is packaging handled? A5: Manual or semi-automatic bagging, using steel pallets or wooden crates for export. Q6: What preparations are needed? A6: Complete civil works, utilities (water, power, gas), and site readiness. Q7: What auxiliary equipment is required? A7: Transformer, weighbridge, boiler, air compressor, oil tank, and forklift.