Jiangsu Olymspan Equipment Eechnology Co.,Ltd
composite autoclave carbon fiber products Carbon fiber drone Tube heat exchanger
- Founded
- 2004
- Headquarters
- Address:Henglin town, Changhzou city, Jiangsu province, China Factory Address:Henglin town, Changhzou city, Jiangsu province, China Phone:86--18626059074(Work Time) Fax:86-0519-88722330 Email:Wei.xia@olymspan.com WhatsApp:+8613861176509
- Factory Area
- 66000m²
- Employees
- 350
- Export Ratio
- 30% - 40%
- Wei.xia@olymspan.com
- Contact via WhatsApp
About Us
JIANGSU OLYMSPAN THERMAL ENERGY EQUIPMENT CO.,LTD is located in Changzhou city, not very far from Shanghai. We are a subcompany of WULIN group, which covers an area about 100,000 square meters, including 50,000 square meters building area. We have an experience team including about 200 skilled-workers, and more than 50 senior engineers. With over 20 years designing, manufacturing and trading experience in providing kinds of industrial equipments such as follows: Carbon FIBER PRODUCTS AEROSPACE AUTOCLAVE COMPOSITE CURING AUTOCLAVE AUTOCLAVE FOR CURING CARBONFIBER /PREPREGS DEFENSE / MILITARY/ MARINES AUTOCLAVE AUTOCLAVE CONTROL SYSTEM FOR COMPOSITE PRODUCT AUTOCLAVE FOR AAC BRICK PRODOCTION LINE AUTOCLAVE FOR CONCRETE PIPE PRODUCTION LINE AUTOCLAVE FOR FIBER CEMENT BOARD PRODUCTION LINE AUTOMATIVE LAMINATED GLASS PRODUTION LINE AERATED AUTOCLAVE CONCRETE
Structured Company Overview
Neutral facts for citation and entity recognition.
- Legal Name
- Jiangsu Olymspan Equipment Eechnology Co.,Ltd
- Established
- 2004
- Ownership
- Private
- Production Model
- OEM / ODM
- Annual Output
- 50Million-55Million
- R&D Team
- 25 engineers
Product Specification Database
Each model is a structured row. No narrative descriptions.
| Name | Model | Type | Material | Applicable Industry |
|---|
Certifications & Compliance
Each record can become a certification entity page.
| Certification | Cert Number | Standard | Authority | Market | Issue Date | Expiry Date | Document |
|---|---|---|---|---|---|---|---|
| IATF | CB01325 | IATF 16949:2016 (1st edition, 01/10/2016) | IATF | Global | 2024-09-25 | 2027-09-24 | |
| URS | 136143/A/0001/UK/En | ISO 45001:2018 | URS | EU | 2024-05-29 | 2027-05-28 | |
| URS | 137839/A/0001/UK/En | ISO 9001:2015 | URS | EU | 2024-09-11 | 2027-09-10 |
Applications & Industries
Taxonomy-backed tags to form industry ↔ supplier ↔ product relationships.
| Industry | Country | Working Condition | Project Type | Function | Operation Mode | Special Requirement | Matched Equipment |
|---|---|---|---|---|---|---|---|
| Aerospace manufacturing, high-end military manufacturing, high-end medical equipment (implantable components), advanced composite material manufacturing, mainly used for the production of aircraft main load-bearing components, missile shells, radar covers, and core components of high-end medical equipment. | CN,RU,US,FR,GB | High end industrial plant, dust-free, non corrosive gas, no electromagnetic interference, environmental temperature controlled at 20-28 ℃, humidity 30% -50%, stable voltage (380V/660V optional), equipped with constant temperature and humidity facilities, equipment needs to operate continuously for a long time to cope with extreme working conditions of high temperature and high pressure. | Mass production projects for aerospace main load-bearing components, manufacturing projects for military core components, production projects for high-end medical equipment components, large-scale production projects for advanced composite materials, and supporting projects for aerospace technology upgrades. | Realize high-temperature and high-pressure curing of high-end composite materials (PEEK, polyimide, etc.), eliminate internal bubbles in the materials, improve component strength, accuracy, and consistency, ensure the safety and reliability of aerospace and military components, meet high-end industry quality standards, and assist in the localization and upgrading of high-end equipment. | Long term continuous operation, running for 20-24 hours per day, supporting fully automated control, with remote diagnosis and fault warning functions, capable of real-time monitoring and automatic adjustment of parameters, equipped with dual redundant control system to ensure uninterrupted operation. | Complies with GJB9001C aviation and military grade standards, with temperature control uniformity of ± 0.3 ℃ - ± 0.5 ℃, pressure stability of ± 0.1MPa, continuous operation cycle of ≥ 8000 hours, multiple safety interlock protection (over temperature, over pressure, leakage emergency), high-strength corrosion-resistant materials for the tank body, professional qualification certification for maintenance personnel, full life cycle management and data traceability functions, and special certification for military and aviation for some models. | Dual redundant control system, remote diagnostic terminal, high-precision temperature and pressure monitoring equipment, heat recovery device, inert gas protection system, vacuum system, professional maintenance tools, emergency pressure relief device, full process quality traceability system, and supporting professional testing equipment. |
| Automobile manufacturing (parts matching), new energy (battery shells, photovoltaic modules), wind power (small parts), civilian composite materials (fitness equipment, medical equipment shells), rail transit parts manufacturing, etc. | CN,IN,VN,TH,BR,RU | The industrial plant environment allows for slight dust, with an ambient temperature of -10-40 ℃, humidity of 30% -70%, and stable voltage (380V). Ventilation facilities are required, and some scenes need to cope with high temperature and high humidity conditions. The equipment needs to have certain anti-corrosion capabilities. | Small and medium-sized production projects, automotive parts supporting production projects, mass production projects for new energy products, wind power parts supporting projects, and large-scale production projects for civilian composite materials. | Realize small and medium batch curing of composite materials, improve product strength, density, and consistency, reduce production losses, improve production efficiency, adapt to diverse production needs of small and medium batch products, and provide qualified composite material components for downstream industries. | Continuous multi batch operation, running for 8-16 hours per day, supporting automatic feeding, curing, and discharging processes, adjustable operating parameters according to production plans, equipped with manual emergency operation mode to cope with sudden shutdown situations. | The equipment runs stably, with an average of ≤ 1.2 failures per month and a fault repair time of ≤ 24 hours. It has a manual and electric dual-purpose quick opening door function and is suitable for curing multiple specifications of products. It has low energy consumption (0.5-0.7 kWh/m ³ per unit volume) and meets industrial production safety standards. It also has anti leakage and anti overheating/overpressure protection. Some export models need to comply with local pressure vessel certification. | Material handling equipment (forklifts, cranes), automated feeding/discharging devices, cooling systems, electrical control systems, sealing replacement tools, vulnerable parts reserves, ventilation and dust removal equipment, and some scenarios are equipped with vacuum systems. |
| University research, new material research and development, and enterprise research and development departments (in the fields of new energy materials, composite materials, polymer materials, etc.), covering subdivision directions such as aerospace material research and development, new energy battery material research and development, and civil composite material formula research and development. | CN,US,GB,JP,DE | University research, new material research and development, and enterprise research and development departments (in the fields of new energy materials, composite materials, polymer materials, etc.), covering subdivision directions such as aerospace material research and development, new energy battery material research and development, and civil composite material formula research and development. The laboratory operates in a normal temperature and pressure environment, with no dust or corrosive gases. The voltage is stable (220V/380V optional), and the ambient temperature is controlled between 15-25 ℃ with a humidity of 40% -60%. It is suitable for intermittent experimental operation and does not require continuous long-term startup. | New material formula research and development project, process parameter debugging project, small batch sample verification project, scientific research project (provincial and national level scientific research project), enterprise technology upgrade research and development project. | Provide high-precision temperature and pressure environment, complete new material curing experiments, optimize process parameters, collect temperature and pressure data during the experimental process, provide technical support for industrial production, verify the performance and adaptability of new composite materials, and shorten the research and development cycle. | Intermittent operation, with a single run duration of 2-8 hours. The equipment is started according to experimental requirements and stopped for cleaning after the experiment is completed. It supports manual/automatic dual-mode operation and can remotely monitor the experimental process and export experimental data. | High precision temperature and pressure control (temperature control ± 0.3 ℃ - ± 0.5 ℃, pressure control ± 0.05MPa), supporting storage and retrieval of multiple experimental parameters, with precise data traceability function, compact equipment size suitable for laboratory space, noise ≤ 60dB, in compliance with scientific research laboratory safety standards, and some export models need to comply with local electrical safety regulations. | High precision sensors, data acquisition devices, remote monitoring terminals, sample placement racks, small cooling devices, vacuum systems (optional), experimental data storage equipment, and gas purification devices for some scenarios. |
Industries (3) → Products (0 models) → Certifications (3)
Manufacturing Capabilities
Core processes and equipment available in-house.
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Customization
Tank volume, temperature control accuracy, pressure range, number of data acquisition points, integration of remote monitoring and data synchronization functions, tank material, experimental mode.
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Lead Time
Standard model 15-25 days; Customized models (including parameter adjustments and new features) take 25-40 days, excluding on-site installation and debugging time (1-3 days for installation and debugging).
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Export Markets
North America , South America , Western Europe , Eastern Europe , Eastern Asia , Southeast Asia , Middle East , Africa , Oceania , Worldwide
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After Sales
Remote suppor / On-site after-sales support
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Quality Control
Full process quality inspection before leaving the factory, including pressure sealing testing, temperature uniformity testing, electrical safety testing, and data acquisition accuracy calibration; On site debugging and verification during delivery to ens
Project References / Cases
Verified project records. Client names anonymized where requested.
| Client Type | Country | Quantity | Application | Duration | Result | Highlight |
|---|---|---|---|---|---|---|
| Aerospace manufacturing enterprise (main load-bearing component manufacturer) | US | 8 units | The main load-bearing components of the aircraft fuselage and wings are cured and adapted to advanced high-temperature composite materials such as PEEK and polyimide, in compliance with GJB9001C aviation grade quality standards, ensuring that the strength, accuracy, and consistency of the components meet the standards. | 7 years | Accumulated production of over 3000 aircraft main load-bearing components, with a product qualification rate of 99.8% and no quality defects, successfully supporting models such as C919 and ARJ21; The continuous operation cycle of the equipment reaches 7800 hours, and the time between failures (MTBF) reaches 1600 hours, far exceeding industry standards; Strictly implement various risk control measures, with no safety accidents occurring for 7 years; Relying on a dual redundant control system, parameter fluctuations are controlled within ± 0.1MPa and ± 0.3 ℃ to ensure product consistency and provide assurance for the safe operation of aerospace equipment. | The maximum temperature can reach 380 ℃ and the maximum pressure is 15MPa, meeting the curing requirements of high-end aviation composite materials; Having a comprehensive safety protection system, multiple pressure and temperature interlock protections, and implementing pressure, temperature, and electrical risk control requirements; Equipped with a dedicated heat recovery device, the heat recovery efficiency is ≥ 82%, and the annual energy saving is 150000 yuan; Equipped with remote diagnosis and full lifecycle management functions, the manufacturer conducts regular follow-up visits, with a fault repair time of ≤ 8 hours. Maintenance personnel are professionally certified to ensure long-term stable operation of the equipment. |
| Wind power component manufacturing enterprises (small and medium-sized) | IN | 6 units | Curing of composite materials for small components of wind turbine blades (blade connectors, reinforcements), mass production of components that meet the high-strength and weather resistance requirements of the wind power industry, ensuring the stability of wind power equipment operation. | 5 years | Realize batch solidification of components, with an average daily output of 400 pieces, meeting the supporting needs of local wind power projects; The weather resistance of the cured components has been improved by 40%, and they can adapt to high temperature, high humidity, and strong wind environments, extending their service life to 15 years; Implement risk control measures for electrical and environmental issues, with equipment operating continuously without faults for a cumulative total of 2800 hours and an annual failure frequency controlled within 10 times; Effectively reducing production costs, saving 300000 yuan in annual operating costs compared to imported equipment, and increasing product market share by 12%. | Suitable for high temperature and high humidity environments, the electrical system adopts anti-corrosion and high temperature resistant design, with excellent insulation performance; Equipped with efficient ventilation facilities, timely discharge harmful gases generated during the solidification process, and implement environmental risk control requirements; The tank body is made of wear-resistant and corrosion-resistant materials, with a long service life and no obvious wear for 5 years; Supporting multiple batches of continuous production, the operating parameters can be flexibly adjusted according to the output, and the cost-effectiveness is outstanding. |
| Small and medium-sized composite material manufacturing enterprises (automotive parts suppliers) | CN | 8 units | Curing of composite materials for automotive components (steering wheel frame, interior parts), suitable for small and medium-sized production, processing 600 products per day to ensure uniform curing and strength compliance with automotive manufacturers' requirements. | 6 years | The equipment runs stably, with a single batch curing time controlled at 2.5 hours, and production efficiency increased by 50% compared to traditional equipment; The product qualification rate has increased from 92% to 99.2%, reducing waste losses by 1.2 million yuan annually; Strictly implement mechanical and environmental risk control measures, equip tank door safety interlocks and material handling auxiliary equipment, and have no personnel injury or equipment damage accidents for 6 years; The annual operating cost is controlled at 120000 yuan, which is 28% more energy-efficient than similar equipment, and the return on investment is 150%. | Modular design of the structure allows for quick switching of production specifications and adaptation to different models of automotive parts solidification; Easy to operate, equipped with a visual control system, and operators can start working after simple training; Equipped with manual and electric dual-purpose quick opening function, it can respond to emergencies such as power outages and implement mechanical risk control requirements; The maintenance frequency is low, with small maintenance every month and comprehensive maintenance every 6 months. The cost of replacing vulnerable parts is low, with an annual replacement cost of only 25000 yuan. |
| Enterprise R&D Department (New Energy Materials Enterprise) | DE | 2 units | Research and development of composite materials for new energy vehicle battery casings, testing the effects of different curing processes on the strength, high temperature resistance, and insulation of battery casings, optimizing production process parameters, and ensuring that battery casings comply with automotive industry safety standards. | 4 years | Successfully developed lightweight and high-strength composite materials for battery casings, with a 35% increase in strength and a 28% decrease in weight after curing. The high-temperature resistance performance reaches 180 ℃, meeting the safety requirements for new energy vehicle batteries; By precise temperature and pressure control through equipment, the process debugging cycle has been shortened by 40%, and research and development costs have been reduced by 25%; Provided standardized process parameters for mass production of enterprises, promoted the large-scale application of new battery casings, and achieved an annual increase in production value of 8 million euros. | Support multi-mode experimental operations, simulate the solidification environment in industrial production, and achieve seamless integration between research and development and production processes; Equipped with imported high-precision sensors, the number of data acquisition points is ≥ 60/time, and the data accuracy reaches ± 0.1 ℃ and ± 0.05MPa; Compliant with EU safety standards, equipped with multiple safety guarantees such as electrical isolation and anti scald protection, and implementing risk control measures for electrical and temperature related risks; Can be integrated with enterprise R&D management systems to achieve automated and data-driven management of experimental processes. |
| University Research Institute (School of Materials Science and Engineering) | CN | 4 units | Research and development of new carbon fiber composite material formula, debugging of curing process parameters, conducting wide temperature range (-40 ℃ to 300 ℃) experiments to verify the compatibility of different resin systems with fiber materials, collecting temperature and pressure data during the curing process, and providing technical support for industrial applications. | 5 | Based on the high-precision temperature control capability of ± 0.5 ℃ of the equipment, we have completed the research and development of 12 new composite material formulas, optimized 6 sets of curing process parameters, published 8 core journal papers, and applied for 3 invention patents; The equipment runs stably, with a total of 1300+experiments completed, complete traceability of experimental data, and no safety accidents occurring; Assisted the team in successfully applying for 2 provincial-level scientific research projects and promoted the transformation of new material technology achievements into enterprises. | Compact in size (with a capacity of 1.2 cubic meters), suitable for small laboratory spaces, and can flexibly adjust experimental parameters; Integrate remote data collection and storage functions, automatically synchronize experimental data to the scientific research management system, and reduce manual recording errors; Equipped with dual alarm and emergency pressure relief functions for over temperature and over pressure, strictly implementing the pressure and temperature risk control requirements mentioned earlier; Easy maintenance, only one part-time technician is needed to complete daily maintenance, with an average of ≤ 0.2 faults per month and a fault repair time of ≤ 3 hours. |
Comparative Positioning
Side-by-side benchmarks against peer manufacturers in this segment.
| Compared To | Difference | Performance Gap | Best For | Cost Difference | Efficiency |
|---|---|---|---|---|---|
| Experimental hot press tank vs high temperature and high pressure aviation grade hot press tank | Experimental hot press tank: miniaturization, multifunctionality, flexible adaptation, focusing on experimental research and parameter debugging, without the need for complex production matching, emphasizing data collection and convenient operation; High temperature and high pressure aviation grade hot press tank: Large scale, high specification, high reliability, focusing on batch curing of high-end products, with a complete safety protection and quality control system, in line with the strict standards of the aerospace industry, high self-sufficiency rate of core components, and emphasis on long-term stable operation and product consistency. | 1. Volume specifications: Experimental volume of 0.5-2 cubic meters, aviation grade volume of 20-100 cubic meters, with the latter having a volume 10-200 times that of the former; 2. Temperature parameters: The maximum temperature for the experimental model is 300 ℃, while the maximum temperature for the aviation grade is 300-400 ℃. The maximum temperature for the latter is 0-33.3% higher than that of the former; 3. Pressure parameters: Experimental type 0-10MPa, aviation grade 10-15MPa, with the latter having a maximum pressure 0-50% higher than the former; 4. Temperature control accuracy: Experimental type ± 0.5 ℃, aviation grade ± 0.3 ℃, the former has an accuracy 40% lower than the latter; 5. Production efficiency: Experimental single experiment takes 2-8 hours, aviation grade single curing takes 4-10 hours, but the latter has a single batch yield 10-50 times that of the former; 6. Continuous operation cycle: Experimental continuous operation ≤ 1000 hours, aviation grade continuous | 1. Experimental hot press tank: used in scientific research and development scenarios for new material development, process optimization, small batch sample testing, suitable for universities, research institutes, and enterprise R&D departments, such as new composite material formula debugging, curing process parameter verification, etc; 2. High temperature and high pressure aviation grade hot press tank: used for the production of core components in aerospace and high-end military industries, used for curing main load-bearing components such as aircraft fuselage, wings, and tail fins, and adapted for curing advanced thermoplastic and high-temperature thermosetting composite materials, such as C919, ARJ21 and other aircraft models. | 1. Purchase cost: Experimental models cost 80000 to 250000 yuan per unit, while aviation grade models cost 2 to 8 million yuan per unit, with the latter costing 8-32 times more than the former; 2. Installation costs: Experimental models cost between 10000 to 30000 yuan, while aviation grade models cost between 300000 to 800000 yuan. The installation cost of the latter is 10-26.7 times that of the former; 3. Annual operating costs: Experimental models cost 20000 to 50000 yuan, while aviation grade models cost 500000 to 1.2 million yuan. The latter has an annual operating cost that is 10-24 times higher than the former; 4. Personnel costs: Experimental models do not require dedicated maintenance personnel, while aviation level models require 4-6 professional maintenance personnel, resulting in an annual increase of 200000 to 400000 yuan in personnel costs; 5. Delivery cycle: Experimental model takes 15-25 days, aviation grade takes 60-120 days, and the latter has a delivery cycle 1.4-3.8 | 1. Energy consumption indicators: The experimental type consumes 0.8-1.2 kWh/m ³ of energy per unit volume, while the aviation grade consumes 0.7-0.9 kWh/m ³ of energy per unit volume. The former has an energy efficiency 14.3% -33.3% higher than the latter; 2. Heating efficiency: The experimental heating rate is 5-10 ℃/min, while the aviation grade heating rate is 2-3 ℃/min. The former has a heating efficiency that is 66.7% -200% higher than the latter; 3. Insulation effect: The experimental insulation loss rate is ≤ 8%/h, and the aviation grade insulation loss rate is ≤ 3%/h. The latter has a better insulation effect than the former by 62.5%; 4. Heat recovery and utilization: Aviation grade equipment is equipped with heat recovery devices, with a heat recovery efficiency of ≥ 80%. Experimental models without dedicated heat recovery devices have a heat recovery efficiency of ≤ 40%, with the latter having a heat recovery efficiency twice that of the former [5] [6]; 5. Energy efficiency |
| Small and medium-sized industrial autoclaves vs high-temperature, high-pressure aviation-grade autoclaves | Small and medium-sized industrial autoclaves: Focus on cost-effectiveness and compatibility with mass production, meeting the curing needs of conventional composite materials. The structural design is simple, and the control system is primarily based on basic automation. High-temperature and high-pressure aviation-grade autoclaves: Focus on high stability, high safety, and high precision, suitable for curing high-end composite materials in aerospace applications. They comply with GJB9001C standards, feature a dual redundant control system, and use more stringent tank materials and sealing technologies, emphasizing product consistency and safety. | 1. Temperature parameters: maximum temperature of 200℃ for small and medium-sized industrial models, and maximum temperature of 300-400℃ for aviation-grade models, with the latter having a maximum temperature 50%-100% higher than the former; 2. Pressure parameters: The maximum pressure for small and medium-sized industrial models is 6MPa, while for aviation-grade models, it ranges from 10 to 15MPa. The latter's maximum pressure is 66.7%-150% higher than the former; 3. Temperature control uniformity: ±1℃ for small and medium-sized industrial models, and ±0.3℃ for aviation-grade models. The former has a uniformity 70% lower than the latter; 4. Pressure stability: Small and medium-sized industrial models ±0.2MPa, aviation-grade models ±0.1MPa, with the latter having a stability 50% higher than the former; 5. Continuous operation cycle: For small and medium-sized industrial models, continuous operation is limited to ≤3000 hours, while for aviation-grade models, it is ≥8000 hours. The latte | 1. Small and medium-sized industrial hot press cans: used in the fields of automobile manufacturing, new energy, civil composite materials, etc., for the production of automotive parts, wind turbine blades, small medical devices and other products, suitable for curing scenarios with small and medium-sized batches and conventional precision requirements; 2. High temperature and high pressure aviation grade hot press tank: used in the aerospace and high-end military industries for curing main load-bearing components such as aircraft fuselage, wings, and engine nacelles. It is suitable for curing advanced composite materials (such as PEEK, polyimide PMR-15, etc.) that meet high temperature and high pressure requirements, and meets aviation grade quality standards. | 1. Purchase cost: Small and medium-sized industrial models cost 300000 to 800000 yuan per unit, while aviation grade models cost 2 to 8 million yuan per unit. The latter has a purchase cost that is 6.7-10 times higher than the former; 2. Installation cost: Small and medium-sized industrial models cost 50000 to 120000 yuan, while aviation grade models cost 300000 to 800000 yuan. The installation cost of the latter is 6-6.7 times that of the former; 3. Annual operating costs: 80000 to 180000 yuan for small and medium-sized industrial models, 500000 to 1.2 million yuan for aviation grade models, with the latter having an annual operating cost 6.25-6.7 times that of the former; 4. Testing costs: The annual testing cost for small and medium-sized industrial vehicles is 10000-20000 yuan, while the annual testing cost for aviation grade vehicles is 80000-150000 yuan. The latter has a testing cost that is 8-7.5 times higher than the former; 5. Delivery cycle: Small and medium-sized industrial | 1. Energy consumption indicators: Small and medium-sized industrial units consume 0.5-0.7 kWh/m ³ of energy per unit volume, while aviation grade units consume 0.7-0.9 kWh/m ³ of energy per unit volume. The former has an energy efficiency 28.6% -22.2% higher than the latter; 2. Heating efficiency: Small and medium-sized industrial models have a heating rate of 3-5 ℃/min, while aviation grade models have a heating rate of 2-3 ℃/min. The former has a heating efficiency 50% -66.7% higher than the latter; 3. Insulation effect: The insulation loss rate of small and medium-sized industrial insulation is ≤ 5%/h, and the insulation loss rate of aviation grade insulation is ≤ 3%/h. The latter has a better insulation effect than the former by 40%; 4. Heat recovery and utilization: Aviation grade equipment is equipped with dedicated heat recovery devices, with a heat recovery efficiency of ≥ 80%. Small and medium-sized industrial models have a heat recovery efficiency of ≤ 60%, with the latter ha |
| Experimental autoclave vs. small and medium-sized industrial autoclave | Experimental autoclave: Emphasizes miniaturization, high precision, and multifunctionality, suitable for laboratory R&D scenarios, supports wide temperature range experiments, integrates data acquisition and remote monitoring functions, focuses on precise parameter control and experimental data traceability; Small and medium-sized industrial autoclave: Emphasizes adaptability for mass production, modular design of structure, balances efficiency and cost, suitable for small and medium-sized batches of composite material curing, focuses on equipment stability and operational convenience. | Experimental autoclave: Emphasizes miniaturization, high precision, and multifunctionality, suitable for laboratory R&D scenarios, supports wide temperature range experiments, integrates data acquisition and remote monitoring functions, focuses on precise parameter control and experimental data traceability; Small and medium-sized industrial autoclave: Emphasizes adaptability for mass production, modular design of structure, balances efficiency and cost, suitable for small and medium-sized batches of composite material curing, focuses on equipment stability and operational convenience. | 1. Experimental autoclave: used by universities, research institutes, and corporate R&D departments for new material formulation research and process parameter tuning, suitable for small batch sample curing, such as carbon fiber prepreg small-scale experiments, new resin curing tests, etc., supporting wide temperature range experiment requirements from -50℃ to 300℃ ; 2. Small and medium-sized industrial autoclaves: For small and medium-sized composite material production enterprises, these autoclaves are used for curing small to medium-sized batches of products such as automotive parts, new energy battery casings, and small aviation components. They are suitable for production scenarios where more than 500 products are processed daily, and meet the specification requirements of a diameter of 1.5-3 meters and an effective length of 4-8 meters | 1. Acquisition cost: Experimental models cost 80,000 to 250,000 yuan per unit, while small and medium-sized industrial models cost 300,000 to 800,000 yuan per unit. The acquisition cost of the latter is 3 to 3.2 times that of the former; 2. Installation cost: Experimental type: 10,000-30,000 yuan; Small and medium-sized industrial type: 50,000-120,000 yuan. The installation cost of the latter is 5-4 times that of the former; 3. Annual operating cost: experimental type: 20,000-50,000 yuan (including electricity and consumables); small and medium-sized industrial type: 80,000-180,000 yuan. The annual operating cost of the latter is 4-3.6 times that of the former; 4. Lead time: 15-25 days for experimental standard models, and 30-45 days for small and medium-sized industrial standard models. The latter has a lead time that is 60%-80% longer than the former. | 1. Energy consumption indicators: The energy consumption per unit volume for experimental models is 0.8-1.2 kWh/m³, while for small and medium-sized industrial models, it is 0.5-0.7 kWh/m³. The latter has an energy efficiency 37.5%-41.7% higher than the former; 2. Heating efficiency: The experimental heating rate is 5-10℃/min, while the heating rate for small and medium-sized industrial models is 3-5℃/min. The former has a heating efficiency 40%-100% higher than the latter; 3. Heat preservation effect: The heat preservation loss rate for experimental models is ≤8%/h, while for small and medium-sized industrial models, it is ≤5%/h. The latter has a heat preservation effect that is 37.5% better than the former; 4. Annual energy saving difference: Based on an annual operation of 8,000 hours, small and medium-sized industrial models save 30,000 to 60,000 yuan in electricity costs compared to experimental models of the same capacity, achieving an energy saving rate of 25% to 30%. |
Risk & Trust Signals
Aggregated data-driven indicators. Not an endorsement.
✓ Overall Trust Score
78/100
Based on 14 verified signals
✓ Positive Signals
Trade RegistrationVerified
Alibaba Gold SupplierYes (5+ yrs)
Audited by 3rd Party2024
On-time Delivery Rate94%
⚠ Risk Items
Operational and management risks1. Operational Control: Establish detailed operational procedures, clarify the operational steps and precautions for each stage, and strictly prohibit unauthorized changes to processes and parameters. Conduct "double confirmation" before operation. Operators must hold valid certificates, wear personal protective equipment, and are strictly prohibited from working while fatigued or leaving their posts in violation of regulations. Clarify the abnormal situation handling process, immediately shut down the machine and report any abnormalities found, and strictly prohibit unauthorized handling.
2. Monitoring and control: Establish a record book for equipment operation, detailing operating parameters, operators, equipment status, abnormalities, and disposal results; regularly inspect the implementation of operating procedures to promptly identify any non-compliant operations.
3. Management control: Establish a comprehensive operation management mechanism, clarify the job responsibilities of
Enterprise Measure1. System management: Establish and improve safety management systems, operating procedures, maintenance and care systems, inspection and testing systems, etc. for autoclaves, clarify the responsibilities of each department and position, and implement a level-by-level responsibility system; regularly revise the systems to ensure their applicability and effectiveness; establish a mechanism for supervising the implementation of the systems, and seriously investigate the responsibilities for irregular operations and inadequate implementation of the systems.
2. Personnel management: Strictly review the qualifications of operating personnel, and prohibit unlicensed personnel from taking up their posts; provide pre-job training for new employees and regular training for existing employees, and carry out warning education by combining typical accident cases; regularly conduct skill assessments and health checks for operating personnel, and arrange work shifts reasonably to avoid fatigue opera
Environmental and material risks1. Environmental and Material Control: Clean up residual materials in the tank in a timely manner to avoid corrosive and flammable material residues; standardize material stacking and strictly prohibit the storage of flammable, explosive, and corrosive items in the operation area; keep the ground in the operation area clean and tidy, promptly clean up water and oil stains; ensure good ventilation in the operation area and promptly discharge harmful gases and vapors; strictly control the quality of materials to prevent contaminated materials from entering the tank.
2. Monitoring and control: Regularly inspect the operating status of ventilation facilities in the operation area, monitor the concentration of harmful gases, and set gas concentration warning thresholds; regularly check the storage and cleaning of materials, and promptly identify and address potential hazards.
3. Operational Control: Operators must strictly adhere to the material handling procedures to clean up residual mate
Enterprise Measure1. System management: Establish specialized systems for environmental management and material handling in operational areas, clarify requirements for material storage, cleaning, ventilation, etc., and implement environmental and material management responsibilities.
2. Equipment and Environmental Management: Equip with qualified ventilation facilities and material storage equipment, regularly maintain the ventilation facilities to ensure normal operation; regularly clean the operation area, standardize material stacking, divide material storage areas, and strictly prohibit the unauthorized storage of hazardous materials.
3. Personnel management: Conduct environmental and material safety training for operators, standardize material handling and environmental cleaning procedures, and enhance risk identification capabilities; regularly conduct emergency response training for poisoning and suffocation.
4. On-site and emergency management: Set up warning signs such as "Danger of Poor Ventil
Electrical Risks1. Electrical safety control: Select electrical equipment and wiring that are resistant to high temperatures, corrosion-resistant, and have good insulation properties; install leakage protection and short-circuit protection devices; before cleaning, maintaining, and repairing equipment, the power must be cut off and electrical isolation must be carried out, with warning signs posted; regularly inspect and maintain the electrical system, and promptly replace aging and damaged components.
2. Monitoring and Control: Monitor the operational status of the electrical system in real-time, and immediately shut down the system for disposal if abnormalities such as line heating or electrical leakage are detected; regularly inspect the insulation performance of electrical equipment and the sensitivity of protective devices, and entrust qualified institutions to conduct electrical safety inspections.
3. Operational Control: Operators are strictly prohibited from touching electrical control compone
Enterprise Measure1. System management: Establish an electrical safety management system for autoclaves, clarify the procedures for maintenance, repair, and inspection of electrical equipment, strictly prohibit unlicensed personnel from engaging in electrical operations, and implement electrical safety responsibilities.
2. Equipment management: Purchase electrical equipment and wiring that meet safety standards, with a focus on testing insulation performance and protective devices during acceptance inspection; establish maintenance records for electrical equipment, conduct regular inspections and repairs, and promptly replace aging components; regularly entrust qualified institutions to conduct electrical safety inspections, and ensure that hidden hazards are rectified before operation.
3. Personnel management: Conduct specialized training on electrical safety for electrical operators and equipment maintenance personnel, and only allow them to take up their posts after passing the assessment; regularly
Mechanical Risks1. Mechanical safety control: The tank door is equipped with a safety interlock device to ensure that the pressure inside the tank can only be opened/closed after it has been reduced to a safe value. It adopts a manual and electric dual-use quick-opening door design to cope with emergencies such as power outages. Auxiliary equipment for material handling, such as cranes and forklifts, is equipped to standardize the handling process and reduce manual operations. Regular inspections are conducted on the structural integrity of components such as the tank body, tank door, and pipelines, and any wear or deformation issues are promptly addressed.
2. Operational Control: Strictly adhere to the tank door operation procedures, and confirm the effectiveness of safety interlocks before proceeding. Standardize material handling to prevent collisions with the tank body. In case of emergencies such as power outages, correctly utilize the manual quick-opening function, and refrain from forced operat
Enterprise Measure1. System management: Establish specialized management systems for tank door operations and material handling, clarify inspection cycles and operational standards for mechanical components, and implement job responsibilities.
2. Equipment management: Purchase equipment with tank door safety interlocks and quick-opening mechanisms that meet standards, with a focus on testing mechanical safety performance during acceptance inspection; establish daily maintenance records for mechanical components, conduct regular inspections and repairs, and promptly replace damaged parts; equip with qualified material handling auxiliary equipment, and maintain it regularly to ensure normal operation.
3. Personnel management: Conduct specialized training on mechanical operation for operators, standardize tank door operation and material handling procedures, and ensure that only those who pass the assessment can take up their posts; regularly carry out mechanical risk warning education to avoid illegal ope
Temperature-related Risk1. Temperature safety control: A high-precision temperature control system is employed to monitor the temperature inside the tank in real-time. Upper and lower limit alarms are set, and in case of abnormal temperature, the heating power supply is automatically cut off and the cooling system is activated. A heat-resistant shield is installed on the exterior of the tank. A scientific temperature rise curve is formulated based on the characteristics of the material to control the temperature rise rate and avoid temperature fluctuations. Ventilation facilities are installed in the operation area to promptly exhaust high-temperature steam.
2. Monitoring and control: Monitor the temperature and temperature rise rate inside the tank in real time, and immediately trigger an alert in case of abnormal parameters; regularly inspect the temperature control system and cooling system to promptly identify and rectify faults; record temperature operation data to facilitate the tracing of potential haz
Enterprise Measure1. System management: Establish operating procedures for temperature control in autoclaves, specifying requirements for heating rate, temperature range, and heat protection measures, and regularly revise and improve them.
2. Equipment management: Purchase high-precision temperature control equipment, with a focus on inspecting temperature monitoring and cooling systems during acceptance; regularly maintain the temperature control system, anti-scalding shields, and ventilation facilities, and promptly replace aging components; entrust qualified institutions to inspect temperature-related equipment to ensure compliance with safety standards.
3. Personnel management: Conduct specialized training on temperature operations to teach operators to identify temperature anomalies and wear heat-resistant protective equipment correctly; regularly organize emergency response training for fires and burns to enhance emergency response capabilities.
4. On-site and emergency management: Set up "Danger!
Pressure-related Risks1. Pressure safety control: Equipped with multiple independent safety interlock devices (automatic pressure interlock, manual interlock, and ultra-high pressure alarm device), it automatically alarms, performs emergency pressure relief, and cuts off the power supply to the pressurization system when the pressure approaches the dangerous value; qualified pressure relief valves and rupture discs are installed, and regular calibration is performed to ensure sensitivity and reliability; silicone inflatable sealing technology is adopted to enhance the sealing performance of the tank door; the rate of pressure rise and fall is controlled to avoid impact on the tank body caused by sudden pressure changes.
2. Monitoring and Control: Conduct real-time monitoring of pressure parameters within the tank, establish abnormal warning thresholds, and immediately trigger audible and visual alarms in case of parameter exceedances. Regularly inspect the tank wall thickness, weld quality, and pressure-rel
Enterprise Measure1. System management: Establish a specialized management system for pressure safety in autoclaves, clarifying procedures for pressure parameter control, safety accessory verification, leakage handling, etc., and implementing responsibilities for each position.
2. Equipment management: When purchasing equipment, strictly review the pressure safety-related configurations. Upon arrival, conduct joint inspections of key components such as pressure control systems and seals. Establish a regular calibration ledger for pressure safety accessories and entrust qualified institutions to conduct inspections and testing. Regularly maintain tank bodies and pipeline connections, promptly replace aging seals, and prevent "operating with defects".
3. Personnel management: Conduct specialized training on pressure safety for operators, clarify the procedures for handling pressure anomalies, and ensure that only those who pass the assessment can take up their posts; regularly conduct pressure risk warnin
ℹ Additional Info
Last Verified2026-04-22 15:09:19
Data SourcesAICPA, Alibaba, TÜV
Profile Completeness91%
Purchase & Trade Information
Trading terms and procurement details.
ℹ Purchase Details
MOQ1unit
Delivery MethodPrecio personalizado
AcceptancePre-shipment test
Payment TermsL/C, T/T, Western Union, D/A
Product Comparison
Comparative analysis against alternative solutions.
| Compared To | Difference | Performance Gap | Best For | Cost Difference | Efficiency |
|---|---|---|---|---|---|
| Experimental hot press tank vs high temperature and high pressure aviation grade hot press tank | Experimental hot press tank: miniaturization, multifunctionality, flexible adaptation, focusing on experimental research and parameter debugging, without the need for complex production matching, emphasizing data collection and convenient operation; High temperature and high pressure aviation grade hot press tank: Large scale, high specification, high reliability, focusing on batch curing of high-end products, with a complete safety protection and quality control system, in line with the strict standards of the aerospace industry, high self-sufficiency rate of core components, and emphasis on long-term stable operation and product consistency. | 1. Volume specifications: Experimental volume of 0.5-2 cubic meters, aviation grade volume of 20-100 cubic meters, with the latter having a volume 10-200 times that of the former; 2. Temperature parameters: The maximum temperature for the experimental model is 300 ℃, while the maximum temperature for the aviation grade is 300-400 ℃. The maximum temperature for the latter is 0-33.3% higher than that of the former; 3. Pressure parameters: Experimental type 0-10MPa, aviation grade 10-15MPa, with the latter having a maximum pressure 0-50% higher than the former; 4. Temperature control accuracy: Experimental type ± 0.5 ℃, aviation grade ± 0.3 ℃, the former has an accuracy 40% lower than the latter; 5. Production efficiency: Experimental single experiment takes 2-8 hours, aviation grade single curing takes 4-10 hours, but the latter has a single batch yield 10-50 times that of the former; 6. Continuous operation cycle: Experimental continuous operation ≤ 1000 hours, aviation grade continuous | 1. Experimental hot press tank: used in scientific research and development scenarios for new material development, process optimization, small batch sample testing, suitable for universities, research institutes, and enterprise R&D departments, such as new composite material formula debugging, curing process parameter verification, etc; 2. High temperature and high pressure aviation grade hot press tank: used for the production of core components in aerospace and high-end military industries, used for curing main load-bearing components such as aircraft fuselage, wings, and tail fins, and adapted for curing advanced thermoplastic and high-temperature thermosetting composite materials, such as C919, ARJ21 and other aircraft models. | 1. Purchase cost: Experimental models cost 80000 to 250000 yuan per unit, while aviation grade models cost 2 to 8 million yuan per unit, with the latter costing 8-32 times more than the former; 2. Installation costs: Experimental models cost between 10000 to 30000 yuan, while aviation grade models cost between 300000 to 800000 yuan. The installation cost of the latter is 10-26.7 times that of the former; 3. Annual operating costs: Experimental models cost 20000 to 50000 yuan, while aviation grade models cost 500000 to 1.2 million yuan. The latter has an annual operating cost that is 10-24 times higher than the former; 4. Personnel costs: Experimental models do not require dedicated maintenance personnel, while aviation level models require 4-6 professional maintenance personnel, resulting in an annual increase of 200000 to 400000 yuan in personnel costs; 5. Delivery cycle: Experimental model takes 15-25 days, aviation grade takes 60-120 days, and the latter has a delivery cycle 1.4-3.8 | 1. Energy consumption indicators: The experimental type consumes 0.8-1.2 kWh/m ³ of energy per unit volume, while the aviation grade consumes 0.7-0.9 kWh/m ³ of energy per unit volume. The former has an energy efficiency 14.3% -33.3% higher than the latter; 2. Heating efficiency: The experimental heating rate is 5-10 ℃/min, while the aviation grade heating rate is 2-3 ℃/min. The former has a heating efficiency that is 66.7% -200% higher than the latter; 3. Insulation effect: The experimental insulation loss rate is ≤ 8%/h, and the aviation grade insulation loss rate is ≤ 3%/h. The latter has a better insulation effect than the former by 62.5%; 4. Heat recovery and utilization: Aviation grade equipment is equipped with heat recovery devices, with a heat recovery efficiency of ≥ 80%. Experimental models without dedicated heat recovery devices have a heat recovery efficiency of ≤ 40%, with the latter having a heat recovery efficiency twice that of the former [5] [6]; 5. Energy efficiency |
| Small and medium-sized industrial autoclaves vs high-temperature, high-pressure aviation-grade autoclaves | Small and medium-sized industrial autoclaves: Focus on cost-effectiveness and compatibility with mass production, meeting the curing needs of conventional composite materials. The structural design is simple, and the control system is primarily based on basic automation. High-temperature and high-pressure aviation-grade autoclaves: Focus on high stability, high safety, and high precision, suitable for curing high-end composite materials in aerospace applications. They comply with GJB9001C standards, feature a dual redundant control system, and use more stringent tank materials and sealing technologies, emphasizing product consistency and safety. | 1. Temperature parameters: maximum temperature of 200℃ for small and medium-sized industrial models, and maximum temperature of 300-400℃ for aviation-grade models, with the latter having a maximum temperature 50%-100% higher than the former; 2. Pressure parameters: The maximum pressure for small and medium-sized industrial models is 6MPa, while for aviation-grade models, it ranges from 10 to 15MPa. The latter's maximum pressure is 66.7%-150% higher than the former; 3. Temperature control uniformity: ±1℃ for small and medium-sized industrial models, and ±0.3℃ for aviation-grade models. The former has a uniformity 70% lower than the latter; 4. Pressure stability: Small and medium-sized industrial models ±0.2MPa, aviation-grade models ±0.1MPa, with the latter having a stability 50% higher than the former; 5. Continuous operation cycle: For small and medium-sized industrial models, continuous operation is limited to ≤3000 hours, while for aviation-grade models, it is ≥8000 hours. The latte | 1. Small and medium-sized industrial hot press cans: used in the fields of automobile manufacturing, new energy, civil composite materials, etc., for the production of automotive parts, wind turbine blades, small medical devices and other products, suitable for curing scenarios with small and medium-sized batches and conventional precision requirements; 2. High temperature and high pressure aviation grade hot press tank: used in the aerospace and high-end military industries for curing main load-bearing components such as aircraft fuselage, wings, and engine nacelles. It is suitable for curing advanced composite materials (such as PEEK, polyimide PMR-15, etc.) that meet high temperature and high pressure requirements, and meets aviation grade quality standards. | 1. Purchase cost: Small and medium-sized industrial models cost 300000 to 800000 yuan per unit, while aviation grade models cost 2 to 8 million yuan per unit. The latter has a purchase cost that is 6.7-10 times higher than the former; 2. Installation cost: Small and medium-sized industrial models cost 50000 to 120000 yuan, while aviation grade models cost 300000 to 800000 yuan. The installation cost of the latter is 6-6.7 times that of the former; 3. Annual operating costs: 80000 to 180000 yuan for small and medium-sized industrial models, 500000 to 1.2 million yuan for aviation grade models, with the latter having an annual operating cost 6.25-6.7 times that of the former; 4. Testing costs: The annual testing cost for small and medium-sized industrial vehicles is 10000-20000 yuan, while the annual testing cost for aviation grade vehicles is 80000-150000 yuan. The latter has a testing cost that is 8-7.5 times higher than the former; 5. Delivery cycle: Small and medium-sized industrial | 1. Energy consumption indicators: Small and medium-sized industrial units consume 0.5-0.7 kWh/m ³ of energy per unit volume, while aviation grade units consume 0.7-0.9 kWh/m ³ of energy per unit volume. The former has an energy efficiency 28.6% -22.2% higher than the latter; 2. Heating efficiency: Small and medium-sized industrial models have a heating rate of 3-5 ℃/min, while aviation grade models have a heating rate of 2-3 ℃/min. The former has a heating efficiency 50% -66.7% higher than the latter; 3. Insulation effect: The insulation loss rate of small and medium-sized industrial insulation is ≤ 5%/h, and the insulation loss rate of aviation grade insulation is ≤ 3%/h. The latter has a better insulation effect than the former by 40%; 4. Heat recovery and utilization: Aviation grade equipment is equipped with dedicated heat recovery devices, with a heat recovery efficiency of ≥ 80%. Small and medium-sized industrial models have a heat recovery efficiency of ≤ 60%, with the latter ha |
| Experimental autoclave vs. small and medium-sized industrial autoclave | Experimental autoclave: Emphasizes miniaturization, high precision, and multifunctionality, suitable for laboratory R&D scenarios, supports wide temperature range experiments, integrates data acquisition and remote monitoring functions, focuses on precise parameter control and experimental data traceability; Small and medium-sized industrial autoclave: Emphasizes adaptability for mass production, modular design of structure, balances efficiency and cost, suitable for small and medium-sized batches of composite material curing, focuses on equipment stability and operational convenience. | Experimental autoclave: Emphasizes miniaturization, high precision, and multifunctionality, suitable for laboratory R&D scenarios, supports wide temperature range experiments, integrates data acquisition and remote monitoring functions, focuses on precise parameter control and experimental data traceability; Small and medium-sized industrial autoclave: Emphasizes adaptability for mass production, modular design of structure, balances efficiency and cost, suitable for small and medium-sized batches of composite material curing, focuses on equipment stability and operational convenience. | 1. Experimental autoclave: used by universities, research institutes, and corporate R&D departments for new material formulation research and process parameter tuning, suitable for small batch sample curing, such as carbon fiber prepreg small-scale experiments, new resin curing tests, etc., supporting wide temperature range experiment requirements from -50℃ to 300℃ ; 2. Small and medium-sized industrial autoclaves: For small and medium-sized composite material production enterprises, these autoclaves are used for curing small to medium-sized batches of products such as automotive parts, new energy battery casings, and small aviation components. They are suitable for production scenarios where more than 500 products are processed daily, and meet the specification requirements of a diameter of 1.5-3 meters and an effective length of 4-8 meters | 1. Acquisition cost: Experimental models cost 80,000 to 250,000 yuan per unit, while small and medium-sized industrial models cost 300,000 to 800,000 yuan per unit. The acquisition cost of the latter is 3 to 3.2 times that of the former; 2. Installation cost: Experimental type: 10,000-30,000 yuan; Small and medium-sized industrial type: 50,000-120,000 yuan. The installation cost of the latter is 5-4 times that of the former; 3. Annual operating cost: experimental type: 20,000-50,000 yuan (including electricity and consumables); small and medium-sized industrial type: 80,000-180,000 yuan. The annual operating cost of the latter is 4-3.6 times that of the former; 4. Lead time: 15-25 days for experimental standard models, and 30-45 days for small and medium-sized industrial standard models. The latter has a lead time that is 60%-80% longer than the former. | 1. Energy consumption indicators: The energy consumption per unit volume for experimental models is 0.8-1.2 kWh/m³, while for small and medium-sized industrial models, it is 0.5-0.7 kWh/m³. The latter has an energy efficiency 37.5%-41.7% higher than the former; 2. Heating efficiency: The experimental heating rate is 5-10℃/min, while the heating rate for small and medium-sized industrial models is 3-5℃/min. The former has a heating efficiency 40%-100% higher than the latter; 3. Heat preservation effect: The heat preservation loss rate for experimental models is ≤8%/h, while for small and medium-sized industrial models, it is ≤5%/h. The latter has a heat preservation effect that is 37.5% better than the former; 4. Annual energy saving difference: Based on an annual operation of 8,000 hours, small and medium-sized industrial models save 30,000 to 60,000 yuan in electricity costs compared to experimental models of the same capacity, achieving an energy saving rate of 25% to 30%. |