China Xi'an Brictec Engineering Co., Ltd. Company News

Refractory Bricks for Tunnel Kilns in Clay Sintered Brick Plants Tunnel kilns are continuous high-temperature firing systems characterized by long structures and multiple thermal zones. Each section operates under different temperature, atmosphere, and mechanical stress conditions. Therefore, the proper selection and configuration of refractory bricks are critical for kiln performance, energy efficiency, and service life. I. Types and Properties of Refractory Bricks Used in Tunnel Kilns 1. Main Types by Material No. Refractory Type Major Composition Service Temperature (°C) Main Features Typical Applications 1 High Alumina Brick Al₂O₃ ≥ 55% 1300–1600 High compressive strength, good slag resistance, poor thermal shock resistance Firing zone roof, kiln door, flame-contact areas 2 Mullite Brick 3Al₂O₃·2SiO₂ 1350–1700 Low thermal expansion, excellent thermal shock resistance, no deformation Firing zone roof and wall, insulation zone 3 Cordierite Brick 2MgO·2Al₂O₃·5SiO₂ 1250–1400 Very low thermal expansion, excellent thermal shock resistance Lower firing zone, transition area 4 Lightweight High Alumina Brick Porous Al₂O₃ ≥ 50% ≤1350 Lightweight, excellent insulation Insulation layer, secondary wall, roof upper layer 5 Fire Clay Brick Al₂O₃ 30–45% 1200–1350 Economical, easy to construct, moderate thermal shock resistance Preheating zone, outer wall, flue lining 6 Insulating Brick SiO₂–Al₂O₃ ≤1100 Low thermal conductivity, lightweight Outer wall insulation layer 7 Silica Brick SiO₂ ≥ 95% 1650–1700 Excellent creep resistance at high temperature, acid-resistant Upper roof of firing zone, kiln head 8 Wear-Resistant Brick High-alumina or mullite-based composite ≤1400 Excellent abrasion and impact resistance Car wheel zone, track edge, kiln car top 9 Silicon Carbide Brick (SiC) SiC ≥ 70% 1500–1650 High thermal conductivity, oxidation and erosion resistance Burner zone, flame impact area, car base 10 Castable / Precast Block High alumina, mullite, or SiC-based 1300–1600 Good integrity and air-tightness Burner ports, arches, sealing joints 11 Ceramic Fiber Board / Blanket Al₂O₃ + SiO₂ ≤1400 Lightweight, excellent insulation, easy installation External insulation, kiln doors, wall lining 12 Shaped / Custom Brick Custom composition Varies Precision fit, customized geometry Burner brick, arch foot, transition pieces   II. Refractory Configuration and Construction Standards in Tunnel Kiln Design 1. Recommended Material Configuration by Kiln Section Kiln Section Recommended Brick Types Thickness (mm) Temperature (°C) Description Roof (Firing Zone) Mullite / Cordierite + Lightweight High Alumina + Ceramic Fiber 500–550 1250–1300 Combines high strength and insulation Wall (Firing Zone) High Alumina / Mullite + Lightweight Alumina + Fiber Board 500 1200–1300 Inner heat-resistant, outer insulating Wall (Preheating Zone) Fire Clay + Lightweight Alumina 400–500 900–1100 Emphasizes thermal shock resistance Insulation Zone Cordierite + Insulating Brick 400 900–1000 Reduces heat loss Flue Lining Fire Clay / SiC Brick 250–350 800–1000 High erosion resistance Kiln Door / Sealing Panels Mullite + Fiber Board + Steel Plate 450–500 1100–1200 Combines insulation and mechanical strength Kiln Car Surface Cordierite / SiC / High Alumina Brick 230 1000–1250 Load-bearing and wear-resistant Kiln Car Insulation Layer Insulating Brick + Ceramic Fiber 200–250 ≤900 Reduces heat conduction Burner Port / Arch Foot SiC / Castable Blocks Custom 1300–1500 High thermal shock and erosion resistance   2. Construction and Masonry Standards Item Technical Requirements Brick Joints ≤ 2 mm; staggered joints ≥ 1/4 brick length Anchoring Stainless steel anchors every 5 brick layers Mortar Use matching refractory mortar (same base material) Construction Sequence Build walls first, then arches; inner lining before outer layer Drying & Heating-Up Initial heating rate ≤ 30°C/hour to prevent cracks Arch Control Accurate curvature control to avoid stress concentration Joints Sealing High-temp sealing compound or ceramic fiber filling   III. Standards for Qualified Refractory Materials 1. Appearance and Dimensional Tolerance (per GB/T 2992.1, GB/T 16544) Item Requirement Surface Smooth, no cracks, chips, or dense pores Dimensional Tolerance ±2 mm in length, width, and height Density Uniformity ≤ ±0.05 g/cm³ variation within the same batch   2. Physical and Chemical Properties (Ref. GB/T 3995, GB/T 10325) Property High Alumina Mullite Cordierite Fire Clay Bulk Density (g/cm³) 2.3–2.6 2.4–2.7 1.9–2.2 2.0–2.2 Apparent Porosity (%) 18–22 15–20 25–30 22–26 Cold Crushing Strength (MPa) ≥60 ≥70 ≥45 ≥35 Permanent Linear Change (%) ±0.2 ±0.3 ±0.3 ±0.4 Refractoriness Under Load (°C) ≥1450 ≥1600 ≥1400 ≥1350 Thermal Shock Resistance (cycles 900°C–water) ≥20 ≥25 ≥30 ≥15   3. Inspection and Acceptance Procedure Raw Material Inspection Chemical composition (Al₂O₃, SiO₂, Fe₂O₃ content) Phase analysis (XRD test) Finished Product Testing Dimensional and visual inspection Fired bulk density and compressive strength test Thermal shock resistance test Documentation Factory test report with chemical and physical data Quality certificate compliant with GB/T, ISO, or ASTM standards On-site Verification Random sampling of ≥10% for re-test before use Only approved materials may be used in kiln construction   IV. Selection Principles for Refractory Materials Principle Description Temperature Matching Select materials according to thermal zones and service temperature Thermal Shock Resistance Priority Roofs and burner zones require mullite or cordierite bricks Mechanical Strength Coordination Use high alumina or SiC bricks for load-bearing areas Insulation Coordination Combine dense inner bricks with lightweight outer layers Supplier Qualification Must hold ISO/GB certification and third-party test reports Sample Verification New suppliers must pass firing performance tests before approval   Conclusion A well-designed refractory system ensures: Stable tunnel kiln operation Low energy consumption Extended kiln service life Consistent product quality Proper selection and configuration of refractory bricks are fundamental to the success of modern clay sintered brick plants and to the overall efficiency of tunnel kiln construction projects.

Xi’an Brictec Iraq KTB Project Enters Accelerated Construction Phase October 2025 Construction Progress Report Project Overview: The project is planned to build three modern tunnel kiln-fired brick production lines, implemented in three phases. After the commissioning of Phase I and Phase II, Xi’an Brictec, following its participation in the Sulaymaniyah Najimadin project, has launched its second turnkey clay brick project in Iraq. The designed production capacity is 1,200 tons/day, covering Iraq’s mainstream brick types — mainly 240×115×75mm, 400×200×200mm, and 200×200×400mm clay fired bricks. At the end of September 2025, the General Manager of Xi’an Brictec personally visited the project site to inspect the construction progress, communicate with the client, and review project updates to ensure the project is completed on time, with guaranteed quality and quantity. KTB Project October 2025 Construction Progress Report In October 2025, the construction of the KTB project has been progressing steadily. The current status is as follows: 1. Construction Team A total of nine professional construction workers from Brictec were dispatched to the project. All of them have many years of experience in brick plant construction and kiln installation, providing solid manpower and technical support for on-site operations. 2. Tunnel Kiln Construction Progress As the core facility of the brick plant, the tunnel kiln’s progress is of utmost importance. Since early September, Xi’an Brictec has assigned skilled masons to accelerate the kiln wall construction. Currently, the kiln wall masonry is well underway, and construction quality strictly follows brick plant standards, ensuring the kiln’s stability, durability, and insulation performance, laying a solid foundation for subsequent installation and operation. 3. Return Line Construction Progress The foundation work of the return line is being carried out as planned according to the process design drawings. The progress is on schedule, and the bearing capacity and stability of the foundation fully meet the design requirements, providing reliable support for future rail installation and kiln car operation. 4. Clay Aging Storage Construction Progress The foundation treatment for the clay aging storage area is also being accelerated. It ensures sufficient load-bearing capacity and strict quality control, laying a firm foundation for the later construction and clay aging storage operations. 5. Next Work Plan The project team will maintain efficient construction, strengthen on-site management, and ensure both quality and safety. Meanwhile, the team will closely monitor weather and other external factors, arrange schedules reasonably, and ensure that the project is completed on time and to high standards. The KTB project team will continue to uphold a professional, efficient, and responsible attitude, fully dedicated to building a high-quality brick plant project. Keywords: Mullite refractory materials, lightweight mullite bricks, tunnel kiln insulation cotton, kiln car bricks, tunnel kiln, dryer.

Xi’an Brictec Shines at the 27th International Conference on Wall and Roof Materials Production Technology and Equipment Expo On September 28, 2025, the highly anticipated 27th International Conference on Wall and Roof Materials Production Technology and Equipment Expo successfully concluded in Xi’an. As one of the most influential events in the industry, the conference attracted numerous well-known domestic enterprises, jointly showcasing cutting-edge technologies and advanced equipment in the field of wall and roof materials production. Xi’an Brictec, together with Brictec’s tunnel kiln burner products, made a remarkable appearance, becoming one of the key highlights of the exhibition. At the expo, Brictec’s tunnel kiln burner, with its unique performance and specialization in thermal engineering products and process equipment for brick plants, attracted significant attention and inquiries from many clay brick manufacturers. Brictec is currently the only burner manufacturer in the market capable of providing professional services from the perspective of overall brick plant process design and tunnel kiln thermal equipment. It is a company that integrates R&D, production, and manufacturing of clay brick tunnel kiln burners. During the exhibition, Brictec’s tunnel kiln burners, known for their high efficiency, energy-saving, and environmentally friendly features, received high praise from visitors, becoming the preferred choice for many customers aiming to enhance production efficiency and product quality. Xi’an Ruitai will continue to uphold the philosophy of “customer-oriented and value-driven by strivers”, listening closely to customer needs, focusing on R&D, and constantly improving product design and performance. Brictec’s tunnel kiln burners will continue to lead the industry in high-quality brick firing solutions, striving to become the No.1 brand in clay brick tunnel kiln burners. The successful conclusion of the 27th International Conference on Wall and Roof Materials Production Technology and Equipment Expo not only provided enterprises in the industry with opportunities for display and exchange but also injected new momentum into the overall development of the wall and roof materials production sector.   News contributed by: JF & LOU

The 27th International Conference on Wall and Roof Materials Production Technology and Equipment Expo 2025 I. Exhibition Content (1) Thematic Reports Policy interpretation by leaders and experts from national ministries; National standards implementation and green evaluation; High-value utilization of solid waste; Performance grading of the brick and tile industry and strategies for pollution reduction and carbon emission reduction; New digital and intelligent production technologies; Energy-saving green wall materials (hollow bricks, blocks, wall panels), architectural decorative terracotta (bricks), colored roof tiles, paving bricks, cultural grey bricks and tiles, brick carvings, etc.; Secondary firing process technology; New drying equipment and energy-saving kiln technologies; New intelligent robots, automatic stacking/unloading/packing equipment; Industrial internet and intelligent manufacturing; Energy-saving, environmental protection, and pollutant treatment technologies; Prefabricated building components and construction technologies; Wall materials and green buildings. (2) Technical Equipment Exhibition Focus on showcasing green, energy-saving, and resource-efficient wall and roof materials, as well as innovative energy-saving manufacturing equipment: New fired wall and roof materials — energy-saving and green thermal insulation wall materials (hollow bricks, blocks, wall panels), architectural decorative terracotta (bricks), colored roof tiles, paving brick production technology and equipment (vacuum extruders, crushers, mixers, rollers, cutters, stackers, robots, unloaders, packing machines, shelving systems, raw material aging units, new dryers, tunnel kilns, kiln operation systems); Traditional architectural grey bricks, tiles, and brick carving technologies and equipment; Autoclaved bricks, AAC blocks (panels), various partition wall panel technologies and equipment; Flue gas purification and environmental protection technologies; New technologies and equipment for solid waste utilization. (3) Related Activities During the exhibition: technical exchanges on R&D, new technologies and processes for energy-saving green wall and roof materials, energy conservation, emission reduction, and equipment applications; factory visits to specialized production lines. Xi’an Wall Materials Research & Design Institute 60th Anniversary Celebration: forums, exhibition of industry achievements, and open visits. II. Brictec Burner Introduction 1. Brictec ISG/ASG High-Speed Natural Gas Burner The Brictec ISG high-speed burner is equipped with automatic ignition and flame detection. It features intelligent automation control, excellent stability, and a wide power regulation range, operating effectively at any temperature. With automatic ignition and temperature control functions, it is an essential ignition device for external-firing tunnel kiln natural gas burner systems and automatic ignition systems. Each burner is equipped with an independent control cabinet, automatic ignition, flame detection, and flue gas fan signal monitoring for safety. The ISG burner eliminates unburned gases inside the tunnel kiln, improving combustion efficiency and reducing harmful emissions. ISG Burner / Technical Parameters: Parameter Specification Applicable Fuels All gaseous fuels (Natural gas, Butane, Propane) Gas Pressure 0.2 – 0.36 bar Heat Power 60 – 150 kW Ignition Method Electrode ignition Operating Modes Max / Min / Stop Flame Detection Ion probe Installation Kiln top or side ASG Burner / Technical Parameters: Parameter Specification Applicable Fuels All gaseous fuels (Natural gas, Butane, Propane) Gas Pressure 0.2 – 2 bar Heat Power 40 – 70 kW Ignition Method None Operating Modes ON – OFF Installation Kiln top 2. Brictec ASNG/2 Dual-Fuel Heavy Oil & Gas Burner The ASNG/2 burner can operate with either liquid fuels (heavy oil, light oil, crude oil, biofuels) or gaseous fuels (natural gas, butane, propane). Switching between fuels requires only a simple switch, no replacement of the burner. A daily oil tank, installed near the kiln, heats and circulates fuel, ensuring continuous flow and avoiding blockages due to low temperature. All tanks are equipped with heaters, safety floats, and necessary accessories for safe and efficient operation. ASNG/2 Burner / Technical Parameters: Parameter Specification Applicable Fuels Liquid: Heavy oil, Light oil, Crude oil, BiofuelsGas: Natural gas, Butane, Propane Gas Pressure 0.2 – 2 bar (for gas) Heat Power 40 – 70 kW Ignition Method Variable (for oil); ON–OFF (for gas) Operating Modes Variable speed (oil) / ON–OFF (gas) Installation Kiln top 3. Brictec PCS Pulverized Coal Burner The Xi’an Brictec PCS pulverized coal burner is an energy-saving, efficient, and simple device used for coal pulverization and feeding in ring kilns and tunnel kilns. It integrates crushing raw coal to below 200 mesh, automatic feeding, and coordination with the temperature control system for fully automated production. PCS Burner / Technical Parameters: Parameter Specification Applicable Fuels Pulverized coal (≤5 mm, Moisture ≤5%, Sulfur ≤4%, HGI ≥50, Calorific value ≥6000 Cal) Heat Power 115 kW per point (max 12 points) Feeding System Automated feeding Installation Tunnel kiln / Ring kiln  

Brictec Successfully Showcased at the 9th Baghdad International Building & Construction Expo (IRAQ BUILDEXPO) Recently, Brictec, a global leader in clay brick plant process design and EPC construction, successfully participated in the 9th Baghdad International Building & Construction Expo (IRAQ BUILDEXPO). At the exhibition, Brictec presented a high-standard brick plant model, highlighting its advanced capabilities in tunnel kiln design, kiln car refractory solutions, and turnkey brick plant projects. The booth attracted strong attention from industry professionals and local contractors, earning high recognition for Brictec’s expertise in energy-efficient, modern brick plant solutions. This event marked an important step for Brictec to expand from the Iraqi market to the broader Middle East region. Through in-depth exchanges with local customers, Brictec will continue to provide efficient, sustainable, and intelligent brick plant solutions, contributing to the quality development of the construction materials industry in Iraq and the Middle East. The exhibition was a great success. Brictec extends its sincere wishes for peace, prosperity, and happiness to the people of Iraq. Overview of the Exhibition About Iraq Build Expo: Iraq Build Expo is the country’s leading international exhibition dedicated to the construction, building materials, infrastructure, and real estate development sectors. Now in its 9th edition, the event will take place from 8–11 September 2025 at the Baghdad International Fairground. As Iraq continues to undergo large-scale reconstruction and modernization, Iraq Build Expo provides a vital platform for local and international companies to showcase their products, services, and technologies to a highly targeted audience of decision-makers, buyers, investors, and project leaders. With participation from over 300 exhibitors and thousands of professional visitors from across Iraq, the Middle East, Europe, and Asia, the expo offers unmatched opportunities to network, build partnerships, and contribute to the future of Iraq’s built environment. Key Features: 1. Extensive exhibition area covering all sectors of construction 2. High-level B2B matchmaking program 3. Live demonstrations and technical presentations 4. Participation of government bodies and private developers Acknowledgements: We would like to express our gratitude to the Iraqi Pyramids Group A.S. for organizing this exhibition. Editor: JF & Lou

Discussion on Pressure Regime in Brictec Tunnel Kiln Firing During tunnel kiln firing, the rationality of the pressure regime has a significant impact on firing results. The kiln pressure regime refers to the distribution pattern of static pressure along the length of the tunnel kiln. By plotting the pressure data of different car positions, a “pressure curve” is obtained. The pressure regime directly determines the flow state of gases inside the kiln, which in turn affects: 1. Heat exchange in the kiln; 2. The amount of combustion air required and the exhaust gas discharged; 3. The uniformity of pressure and temperature distribution inside the kiln.   I. Formation of the Pressure Regime The pressure distribution inside the kiln is the result of multiple gas flows acting together: 1. Cooling zone: A large amount of cold air enters, while heated air is extracted. 2. Firing zone: Fuel combustion generates gases, with the addition of primary air and atomized fuel. Pressure in this zone is usually higher than atmospheric pressure, forming positive pressure. 3. Preheating zone: A large amount of flue gas and water vapor is discharged by the exhaust fan. Kiln pressure is lower than atmospheric pressure, forming negative pressure. During the transition from positive pressure to negative pressure, there exists an interface where the internal kiln pressure equals the external atmospheric pressure. This is called the zero-pressure plane (or zero point/zero position). (1) Before the zero-pressure plane (preheating zone) → Negative pressure zone, beneficial for discharging flue gas and water vapor, but may cause cold air infiltration, leading to thermal stratification and increased temperature difference. (2) After the zero-pressure plane (firing zone) → Positive pressure zone, prevents cold air entry and maintains stable, uniform temperature. II. Control of the Zero-Pressure Position In practical operation, most tunnel kilns maintain the firing zone under slight positive pressure, and set the zero-pressure plane at: 1. The middle of the firing zone; 2. Or around 1/3 of the coal-feeding rows toward the insulation zone; 3. Or slightly behind this position. This allows high-temperature gases to evenly fill the entire brick stack, ensuring uniform heating and insulation of bricks at high temperatures. III. Key Points for Controlling Positive Pressure 1. Advantages of moderate positive pressure: Stable kiln atmosphere, uniform temperature, prevention of cold air entry. 2. Risks of excessive positive pressure: Significant hot gas leakage → increased heat loss; 3. If kiln car bottom sealing is insufficient → hot gases flow downward, possibly leading to: (1) Deformation and damage of kiln car skirts; (2) Wear of sand seal grooves; (3) Evaporation of bearing lubricating oil, causing bearing damage; (4) Deterioration of the working environment. Therefore, tunnel kiln operation should avoid excessive positive pressure and maintain only slight positive pressure.

2025 Xi’an Brictec KTB Project Latest Progress In 2025, Xi’an Brictec will launch its second major engineering project in Iraq — the KTB sintered brick production line. The project plans to build three modern tunnel kiln sintered brick production lines, to be advanced in three phases. After the completion of Phase I and Phase II, the total daily output is expected to reach 900 tons, mainly producing clay sintered bricks with the specification of 240*115*75mm, 400*200*200mm, 200*400*200mm. This project not only consolidates Xi’an Brictec’s leading position in the Middle Eastern market but also provides strong technical support for the upgrading and transformation of Iraq’s building materials industry. Latest construction progress as of August 2025: Third batch of goods arrived at the site Tunnel kiln masonry construction 250T kiln wall construction at the discharge end 650T kiln foundation pit construction Retaining wall construction for Chenhua warehouse V-shaped foundation construction for Chenhua warehouse commenced Copyright Notice: All images are sourced from Brictec Iraq project site photography. Unauthorized use will be pursued for legal liability. Edited by: JF & Lou

Brictec Successfully Completes Thermal Shock Resistance Test for Refractory Bricks, Demonstrating Expertise in Brick Plant Construction With 15 years of experience in complete plant process design and project construction for clay-fired brick production, Brictec has recently completed thermal shock resistance tests for tunnel kiln refractory bricks and kiln car refractory bricks. These tests not only verified the performance of refractory materials under extreme temperature variations but also demonstrated Brictec's professional approach to material selection and quality control in brick plant construction. Importance of Thermal Stability Testing In clay brick production, tunnel kiln refractory bricks and kiln car refractory bricks are directly exposed to high-temperature impacts and frequent thermal cycling. Tunnel kiln bricks must withstand continuous operating temperatures above 1000°C, while kiln car bricks endure severe thermal shocks during the loading/unloading of red brick green bodies. Inadequate thermal stability can lead to cracking and spalling, significantly affecting kiln service life and production safety. Brictec's Rigorous Testing Protocol To ensure refractory bricks meet operational requirements, Brictec has established strict "Refractory Brick Thermal Shock Resistance Testing Standards": Sample Preparation: Specimens cut from production batches according to GB/T 3997.1 Equipment: Program-controlled electric furnace with water quenching system Procedure: Heat specimens to 1100°C for 30 minutes Rapidly quench in 20°C water Repeat cycles until failure occurs Evaluation: Strength retention rate after 20 cycles (≥80% qualified) Quality Assurance for Construction Projects During testing, Brictec utilized temperature monitoring systems integrated with (clay brick making machines) for accurate data collection. Our engineering team paid special attention to refractory performance in actual (red brick making machine) production lines, using test results to select optimal materials for ongoing projects. Key Term Glossary: Clay brick making machine: Core equipment for forming and firing clay bricks Red brick making machine: Automated equipment specialized in standard red brick production Thermal shock resistance: Material's ability to withstand rapid temperature changes without damage Should there be any technical inaccuracies or editorial errors, we welcome corrections and feedback.

Project overview Malaysia CBT decorative bricks production line project is Brictec's flagship model project in Southeast Asia, designed to produce a daily output of 70,000 decorative bricks (215x100x67mm). Due to the molding shift of 6 days per week, the actual daily output is about 85,000 pieces. The main project process for decorative bricks production line: The project adopts wet plastic extrusion process, its drying adopts single layer tunnel dryer with support bar recycling, and firing uses external firing tunnel kiln with flat ceiling of lightweight mullite. The operating equipment can be automatically controlled, and the drying chamber and tunnel kiln are centrally controlled. November Project Phase Summary   1.Drying Chamber Section 1：The cyclone base and main shaft motor on the top of the drying chamber have been installed,22 cyclone cone barrels have been installed and debugged,and 65 fans have been installed; 2：The hot air pipe was produced on November 25,and the welding and assembly were completed; 3：The concrete pouring of 2 out of 4 lines of the internal track of the drying chamber has been completed,and the other 2 lines are expected to be completed before December 8; 4：The ferry lane construction at the vehicle exit has been completed; 5：The hot air feeding blowers have been moved to the installation location; 6：65 cyclone column piers have been poured.   2.Tunnel Kiln Section 1：After the completion of the ceiling beams,85 beams have been installed,along with 1512 secondary beams; 2：The concrete pouring for the tunnel kiln ring beam has been finished; 3：The construction of 2 return lines in the pre-drying chamber has been completed; 4：The foundation construction of the ferry lane at the exit has been completed,and the steel bars of the track beam have been tied,awaiting track installation; 5：The concrete pouring of the moisture exhaust chamber at the entry has been completed, and the case-in-place concrete top plate at the exit has also been completed; 6：The ground of the return line has been excavated,and the crusher will be brought in next week to crush the ground,after which construction will commence; 7：3780 lightweight high-aluminum hanging bricks and 3780 MG-26 polylight mullite ceiling bricks have been bonded.   3.Process Equipment Foundation Section 1：Excavation of box feeder foundation and positioning of super fine roller mill. 4.Arrival Status The second batch of domestic goods 2-4,2-5,and 2-6,total 15 containers arrived at the site,the inventory was completed without any damage or quantity error,the goods were placed in an orderly manner in the designated location of the workshop. 5.On-Site Documentary Pictures    

Several Key Factors Affecting the Output and Energy Consumption of Vacuum Extruder Vacuum extruder is the main equipment in brick and tile industry for producing hollow brick, and its performance directly affects the economic benefit of enterprise. The are four key factors that affect the performance: mud cylinder, auger, head and die of extruder. As long as these four factors are properly configured, combined with a well-designed production process, the extruder can achieve its optimal performance. At present, there is an opinion that a shorter mud cylinder is better, as it reduces load and increases output. In fact, the length of the mud cylinder should depend on different raw materials and the nature of finished product. For material with high plasticity, the cylinder should be shorter; conversely, it should be appropriate longer. For standard brick, the cylinder should be shorter, whereas for hollow brick, it should be appropriate longer. Generally, the number of auger turns in sealing section should meet the turns required to generate pressure. 2.Auger The length of mud cylinder is not the only key factor in determining output, the arrangement of the auger pitch is equally important. It’s worth noting that the arrangement should be tailored to different raw materials. For example, there is a JKR45/45-2.0 vacuum extruder in a brick plant in Jieshou city, Anhui province, has a mud cylinder length of 550 mm, sealing section length of 725 mm, and an auger pitch arrangement of 380, 360×1.76, 380×1/2. The raw material used is plain sedimentary soil. During the test run, the output of KP1 was 6 strips/min, the mud cylinder and the head of the extruder overheated, the mud strip lacked toughness, and severe spiral grain occurred. After analysis, the issue was attributed to an unreasonable pitch arrangement. A new auger was designed with a pitch arrangement of 380, 33x1.92, and 380x1/2, which extended 4 cm into extruder head. It increased the output to 14 strips/min, while reducing the temperature of the head and mud cylinder. It can be seen that the pitch arrangement should be designed based on the characteristics of the raw materials. It is best to analyze the composition and plasticity of the materials before test run and then manufacture the auger accordingly to avoid delays. 3.The die of extruder The quality of the die directly impacts both the quality and output of product. Our approach is to design the KP1 die and the extruder die for non-load-bearing hollow brick based on the composition and plasticity of the local raw materials, as well as the actual condition of the die for standard solid brick. Generally, the taper of the die should be controlled at around 7 - 8. When the plasticity is high, the taper should be enlarged appropriately; when it is low, the taper should be reduced. For example, in a brick factory in Changsha using soft shale with good plasticity, the KP1 die has a length of 155 mm, with an outlet of 250×122 mm and an inlet of 300×185 mm. In another factory in Jieshou, Anhui, the die for non-load-bearing 8-hole hollow brick is made directly from δ=30 steel plate without a taper. Additionally, in Hexian, Anhui, the JKR50/50-2.0 features a KP1 double outlet design with a length of 140 mm, and outlet and inlet of 250×250 mm and 285×285 mm. 4.The head of extruder The shape of the head varies among different manufacturers, but the general structure is the same. It is usually equipped with two types of heads (for sand material, the head is longer, and for material with good plasticity, the head is slightly shorter). In addition, there is another type of internal head that features the die embedded inside the cavity of extruder head, with adjustable length and size of the die. For hollow brick, the manufacturing of the head is divided into two types: combined type and main auger insertion type. In short, the diversity of extruder head also reflects the diversity of raw materials. In conclusion, the above four are the main factors affecting the performance of the extruder, and their optimal combination for different raw materials can make the extruder achieve its best performance. Therefore, preliminary research is crucial for different production lines. For each client, it is important to first study their raw material characteristics before determining the optimal design. At the same time, on-site personnel should possess good skills and be able to come up with best solution for any issues that arise during testing to ensure client satisfaction. The extruder (including both non-vacuum and vacuum extruders) is the main equipment in brick production line. The article discusses the energy-saving measures of extruder from the perspective of installing a reactive power compensator, rational selection of vacuum pump, and the design of auger and mud cylinder, etc: （1）Installing a reactive power compensator in extruder can save energy Installing an energy-saving compensator at the main circuit terminal of extruder motor can improve the power factor of the motor (generally increasing the COSΦ to around 0.95) and save more than 15% of energy, especially in location with low load or where the motor is far from the transformer, where its effect is more significant. （2）The vacuum extruder should be equipped with suitable vacuum pump In the past, vacuum extruder was typically equipped with high-power vacuum pump, leading to significant energy waste. Due to poor sealing, a 450mm vacuum extruder had to be paired with a 22KW vacuum pump, and the vacuum level often failed to meet requirement. In recent years, some brick manufacturers have improved the sealing component of the vacuum system, and the performance of vacuum pump has significantly improved. Now, a 5.5KW mechanical vacuum pump can fully meet the need of 500 mm or even larger vacuum extruder, while maintaining a high vacuum level over the long term. （3）The vacuum extruder should be equipped with optimally designed auger Auger is the core component of the extruder, and its quality plays a decisive role in extruder’s performance. For some extruders, simply improving components such as the auger can reduce electricity consumption by 20% - 30%, while also increasing output by 20% - 30%. The energy-saving effect is significant. （4）Improving the mud cylinder of extruder can reduce energy consumption The length of mud cylinder is also an important factor. Some brick manufacturers believe that a longer mud cylinder is better. However, it not only consumes excessive power but also causes the cylinder to overheat, resulting in a decline in brick quality. Generally, the enclosed length of the auger should not exceed 3 pitches. （5）The vacuum extruder is most energy-saving at its optimal speed. Some brick manufacturers believe that higher extruder speed leads to higher output and lower energy consumption per 10,000 bricks. In fact, with the same material and condition, there is only one optimal speed. Test has shown that the extruder consumes the least energy and achieves the highest output at its optimal speed. Exceeding this speed result in higher energy consumption without any increase in output. （6）Improving production management can make the extruder energy-saving Some brick manufacturers with same conditions have significantly different energy consumption per 10,000 bricks, primarily due to poor management. For example, in production process, the material supply may sometimes be insufficient, causing the extruder to operate inefficiently with low output. At other times, the material supply may be excessive, resulting in the extruder being “overloaded” and requiring frequent shutdown for cleaning, which reduces hourly output. Additionally, poor coordination in production, such as insufficient raw material supply or delay in brick conveyance can lead to shutdown and low output, thereby increasing energy consumption. Furthermore, some manufacturers neglect regular maintenance, failing to replace worn mud cylinder liner or repair gap greater than 20 mm between the auger and the liner, all of which lead to higher energy consumption.