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The main focus is on the development, promotion and industrial application of biomass gasification technology.
A national high-tech enterprise specializing in renewable energy technology development.
SZS series oil/gas hot water boiler is a double-drum, longitudinally placed, D-shaped structure, wit...
View More1. Biomass gasification principle Under certain thermal conditions, biomass raw materials are subjec...
View MoreEnvironmental protection equipment is usually used to remove sulfur dioxide (SO₂) and nitrogen oxide...
View MoreGuangdong Baojie customizes the process technology and configuration plan for each customer.
Guangdong Baojie Environmental Protection Technology Co., Ltd, is a national high-tech enterprise specializing in renewable energy technology development, which mainly carries out the research and development, promotion and industrial application of biomass gasification technology.
A national high-tech enterprise specializing in the development of renewable energy technologies.
Research and development, promotion and industrial application of biomass gasification technology.
R&D and manufacture of biomass gasification equipment, environmental protection equipment, boiler equipment, investment in heating (steam) energy operation and management.
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Our team of engineers has carefully polished and cast stationary and mobile production line solutions for many years.
Quick response and strong technical solution ability self-produced core equipment.
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Read MoreProvide original parts Effectively supply up to thousands of parts Timely supply rate reaches 100%.
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Read MoreThe company's technical team is more professional, efficient and powerful, laying a more solid foundation for the company's subsequent development and technological innovation.
Our team of engineers has carefully polished and cast stationary and mobile production line solutions for many years.
Gas boilers are the unsung heroes of industrial applications, powering factories, heating spaces, and providing essential steam for various processes. However, like any hardworking machine, they require regular maintenance to operate efficiently and safely. Neglecting boiler maintenance can lead to costly downtimes, safety hazards, and reduced energy efficiency. One of the most critical maintenance practices for gas boilers is conducting regular inspections. These inspections should be performed at least annually, or more frequently depending on usage and manufacturer recommendations. During these inspections, trained professionals examine the boiler for signs of wear and tear, leaks, and corrosion. Key components to check include the burner, heat exchanger, and safety valves. For instance, the burner must be inspected to ensure that it’s properly calibrated and free from blockages. A well-tuned burner can improve efficiency by up to 10%, according to the U.S. Department of Energy. Regular inspections not only help identify potential issues before they become major problems but also ensure compliance with safety regulations. Another essential practice is the cleaning and maintenance of various boiler components. Over time, dust, soot, and other residues can accumulate inside the boiler, affecting its efficiency and performance. Regularly cleaning the heat exchanger and burner can help maintain optimal heat transfer and combustion efficiency. Additionally, the boiler’s flue gas passages should be cleared to prevent blockages that can lead to dangerous situations such as backdrafting. For industrial boilers, it’s crucial to have a maintenance schedule that includes periodic cleaning, typically every six months to a year, depending on the operational environment and usage patterns. Advancements in technology have led to the development of sophisticated control systems for gas boilers. These controls monitor various parameters such as pressure, temperature, and flow rates. Regular monitoring and adjustments are vital to ensure that the boiler operates within the specified parameters. Routine calibration of pressure and temperature controls can prevent operational inefficiencies and enhance safety. For example, if the pressure settings are too high, it could lead to unsafe operating conditions or even boiler failure. Keeping a close eye on control settings and making necessary adjustments can significantly improve the reliability and longevity of the gas boiler. Maintaining a gas boiler in an industrial setting is not just a matter of routine; it’s a critical investment in safety, efficiency, and productivity. By adhering to regular inspections, cleaning and maintaining components, and monitoring control systems, businesses can ensure their gas boilers operate at peak performance. The consequences of neglect can be severe, but with proper maintenance practices, industrial facilities can keep the heat on and avoid costly disruptions. Remember, a well-maintained gas boiler is not only a safe boiler but also a cost-effective one!
In today's world, where the quest for sustainable energy solutions is more critical than ever, biomass gasification has emerged as a beacon of hope. But what exactly is a biomass gasifier, and how does it work? A biomass gasifier is a device that converts organic materials—such as agricultural residues, wood chips, and even municipal solid waste—into a gaseous fuel. This process is known as gasification, and it involves breaking down the biomass at high temperatures in a low-oxygen environment. The resulting product, called syngas (synthesis gas), primarily consists of hydrogen, carbon monoxide, and some carbon dioxide. This syngas can then be used to produce electricity, heat, or even be converted into biofuels. The biomass is often moist, so the first step involves drying it to reduce its moisture content. This is crucial because high moisture levels can hinder the gasification process. As the biomass heats up, it undergoes pyrolysis, where it decomposes into solid char, liquid bio-oil, and gaseous products. This stage occurs at temperatures between 300-600°C. The char and remaining biomass are subjected to higher temperatures (around 700-1000°C) in a controlled, oxygen-limited environment. Here, the solid char reacts with steam or carbon dioxide, producing syngas. The raw syngas produced may contain impurities like tar, particulates, and other pollutants. Therefore, it needs to be cleaned and conditioned to make it suitable for use in engines or turbines. Biomass gasification presents several compelling benefits: Renewable Energy Source: Biomass is abundant and can be sustainably sourced. It offers a renewable alternative to fossil fuels, contributing to a reduction in greenhouse gas emissions. Gasification helps in managing waste effectively. Instead of sending organic waste to landfills, it can be transformed into valuable energy. By utilizing locally sourced biomass, communities can become less reliant on imported fossil fuels, enhancing energy security. The syngas produced can be utilized for various applications, from electricity generation to powering vehicles, making it a flexible energy solution. Biomass gasifiers represent a promising technology in the transition to renewable energy sources. By converting organic waste into syngas, they not only provide a sustainable energy solution but also tackle waste management challenges. As we continue to seek innovative ways to power our lives while minimizing our environmental impact, biomass gasification stands out as a viable and effective option. With ongoing advancements in technology and increased awareness of renewable energy benefits, the future of biomass gasifiers looks bright—turning waste into a valuable resource for generations to come.
Green facilities play a significant role in enhancing the quality of life for urban residents, primarily through the following aspects: Green facilities such as parks, green spaces, and street trees can absorb pollutants like dust and harmful gases from the air while releasing oxygen, effectively improving urban air quality and providing residents with a fresher breathing environment. Natural water bodies like wetlands and rivers, along with eco-designed rain gardens and other green facilities, can purify water, reduce pollution, and provide clean water sources for the city while increasing the diversity of urban landscapes. Green facilities provide habitats for wildlife, helping to maintain ecological balance and biodiversity. They offer residents opportunities to observe and connect with nature, enriching their spiritual lives. Urban parks, community green spaces, and other green facilities provide vast recreational areas where residents can walk, jog, cycle, picnic, and enjoy outdoor activities. Green facilities are often equipped with various recreational amenities, such as fitness equipment and children's playgrounds, catering to the needs of different age groups and promoting the physical and mental health of residents. Green facilities offer platforms for community residents to interact and engage with each other. Through collective participation in greening and environmental maintenance, residents enhance mutual understanding and friendship, strengthening community cohesion. Green facilities, with their unique natural and ecological beauty, add vitality and vibrancy to the city, elevating the overall image and character of the urban . Some distinctive green facilities, such as famous city parks or ecological landscapes, often become iconic attractions, drawing a large number of tourists and boosting the city's visibility and reputation. The construction and maintenance of green facilities require significant investment in human, material, and financial resources, which in turn stimulates the growth of related industries such as landscape design, green construction, and environmental materials. The quality of green facilities has become an important consideration for homebuyers. A well-developed green environment can enhance the value of surrounding real estate, offering better returns on investment for residents. Green facilities provide residents with opportunities to connect with nature, helping to alleviate work-related stress, relax the mind, and improve overall health and well-being.Elevating Quality of Life: The development and enhancement of green facilities make the living environment more livable and comfortable for urban residents, thereby improving their overall quality of life.
When a gas leak is detected while using a gas boiler, the following emergency measures should be immediately taken to ensure personal safety and control the leakage situation: Quickly locate and close the main gas valve of the boiler to cut off the gas supply and prevent further leakage.If there is a flame near the valve, use a wet towel or wet clothing to wrap your hand, and try to close the valve to avoid hand injuries. If the gas leak occurs in the boiler room or nearby areas, immediately cut off the power supply to the area to prevent electrical equipment from generating sparks that could trigger an explosion.Ventilate the Area:Open doors and windows to ensure indoor air circulation, reducing the concentration of gas inside and lowering the risk of explosion.Avoid turning on or off any electrical equipment, including lights, exhaust fans, etc., to prevent the creation of sparks. Quickly evacuate the personnel from the leakage site and surrounding areas, and prevent unauthorized personnel from approaching to ensure safety.Establish a warning zone to prevent others from inadvertently entering the hazardous area. Ensure your own safety first, then use a phone outside the danger area to call the local gas company's emergency center or dial 110 to report the leak and request professional assistance.Provide the dispatcher with details about the leak's exact location, the amount of leakage, and whether there are any injuries. Prohibit Open Flames:Strictly prohibit smoking, the use of open flames, or any operations that may generate sparks in and around the leak site to prevent an explosion.Wait for Professional Assistance:Do not attempt to enter the leakage site or fix the leak on your own before professionals arrive.Cooperate with the professionals, providing necessary assistance and information. To prevent gas leaks, users should regularly inspect the gas boiler, its pipes, valves, and other equipment for integrity and proper sealing, and promptly replace any aged or damaged components. Ensure that the environment where the gas boiler is used is well-ventilated and free from flammable or explosive materials. Users should also be knowledgeable about the correct operation of the gas boiler and emergency response procedures so they can act quickly and effectively to protect themselves and others in the event of a leak or other emergency situation.
When evaluating the efficiency of biomass gasifiers in comparison to other biomass energy conversion technologies, it's essential to understand the various mechanisms and factors that influence their performance. Biomass gasification, a process that converts organic materials into syngas (a mixture of carbon monoxide, hydrogen, and methane) through thermal and chemical reactions, holds a unique position in the spectrum of biomass energy technologies. This process involves several stages: pyrolysis, oxidation, reduction, and reforming. Each stage plays a crucial role in breaking down biomass into valuable gases, which can then be used for power generation, heating, or as a chemical feedstock. One of the primary advantages of biomass gasifiers is their ability to produce a versatile fuel in the form of syngas. The efficiency of this conversion depends heavily on the design of the gasifier and the conditions under which it operates. In contrast to direct combustion, which burns biomass to produce heat, gasification generates a cleaner and more efficient energy carrier. This is due to the fact that gasification processes biomass in an oxygen-deficient environment, leading to a higher energy yield compared to direct combustion, where a significant portion of the energy is lost in the form of heat. Gasifiers also have the ability to reduce the volume of solid waste and tar production, which are common by-products in combustion systems. Comparing biomass gasifiers to other biomass energy technologies, such as anaerobic digesters or biodigesters, reveals distinct differences. Anaerobic digestion converts organic materials into biogas (primarily methane and carbon dioxide) through microbial processes. While anaerobic digesters are effective for managing organic waste and producing biogas, their efficiency in energy conversion is generally lower than that of biomass gasification. This is because the digestion process tends to produce lower energy content gases and often requires additional infrastructure for handling and processing the digestate. Furthermore, gasification can handle a broader range of feedstocks and is not limited to materials that are primarily composed of wet or organic waste, unlike anaerobic digesters. On the other hand, technologies such as biomass boilers and combined heat and power (CHP) systems operate through direct combustion or co-firing biomass with fossil fuels. These systems are straightforward and often less complex to operate than gasifiers, but they typically suffer from lower efficiency when it comes to converting biomass into usable energy. Direct combustion systems tend to have higher emissions and less flexibility in feedstock types. Although CHP systems can utilize biomass combustion for both electricity and heat, they generally do not achieve the same level of syngas quality and efficiency as gasifiers, particularly in terms of cleaning and optimizing the fuel for specific applications. In terms of commercial value, biomass gasifiers offer several advantages. They can achieve high thermal efficiency and produce syngas that can be cleaned and used for a variety of applications, including power generation and as a chemical feedstock. This versatility, combined with the potential for lower emissions and reduced waste, makes biomass gasifiers an attractive option in both small-scale and industrial applications. However, the initial cost of installation and the complexity of operation can be higher compared to simpler combustion systems or anaerobic digesters. Biomass gasifiers generally provide superior efficiency in converting biomass into valuable energy compared to direct combustion and anaerobic digestion. They produce a higher quality fuel with greater flexibility and cleaner operation, though they come with higher upfront costs and operational complexity. Understanding these factors can help stakeholders make informed decisions when choosing the most appropriate biomass energy technology for their specific needs and conditions.
The SZS series oil/gas hot water boiler stands out for its advanced design, which significantly enhances energy efficiency. This design is based on a double-drum, longitudinally placed, D-shaped structure, integrating several key features that contribute to its high performance. Central to its efficiency is the arrangement of the furnace and convection tube bundle. The furnace, situated on the right side of the boiler, is encased by membrane water-cooled walls. These walls are designed to create a sealed environment that effectively isolates the furnace from the convection tube bundle. This separation is crucial because it allows for more precise control of the combustion process and minimizes heat loss. By keeping the furnace environment tightly controlled, the boiler can achieve optimal combustion temperatures, which improves overall fuel utilization. The convection tube bundle on the left side of the boiler is engineered to maximize heat transfer. This bundle features both staggered and straight structures, which enhance the flow and distribution of flue gases. As the hot gases move through these tubes, their heat is efficiently transferred to the water or steam in the boiler, raising its temperature. This efficient heat transfer reduces the amount of fuel needed to achieve the desired temperature, thus improving the boiler's efficiency. An important feature of the SZS series is the spiral fin tube condensing economizer. Positioned at the end of the convection tube bundle, this component plays a critical role in capturing and reusing residual heat from the flue gases. As the gases pass through the economizer, their remaining thermal energy is transferred to the water or steam. This process not only recovers heat that would otherwise be lost but also lowers the temperature of the exhaust gases before they exit through the chimney. By enhancing the heat recovery process, the economizer reduces the overall energy consumption of the boiler, leading to cost savings and reduced environmental impact. The SZS series boiler's design intricately combines efficient combustion technology, advanced heat transfer mechanisms, and effective heat recovery systems. This thoughtful integration of components results in a highly efficient boiler that minimizes fuel consumption, reduces operational costs, and contributes to a lower environmental footprint. The evolution of such technologies reflects the ongoing efforts to enhance energy efficiency in industrial and commercial heating systems.
In the thermal energy management of Biomass Gasifier, heat distribution and utilization are the key links that determine the efficiency, economy and sustainability of the system. The core elements of this process will be discussed in detail below. During the operation of the biomass gasifier, a large amount of heat energy is generated, which needs to be reasonably distributed among different process steps, including feedstock pretreatment, gasification reaction maintenance, gas purification and waste heat recovery. The design of optimizing heat distribution is the basis for ensuring efficient operation of the system. Biomass feedstocks usually need to be dried to improve gasification efficiency. By allocating part of the waste heat to the feedstock drying stage, the dependence on external heat sources can be reduced and energy costs can be reduced. Maintaining the optimal temperature of the gasification reaction is crucial to ensure gasification efficiency. Reasonable heat distribution can ensure that the temperature of the reaction zone is stable and avoid the decrease of gasification efficiency due to temperature fluctuations. Waste heat recovery is a key measure to improve the energy utilization rate of the biomass gasification system. Through an efficient waste heat recovery device, the heat in the high-temperature syngas can be reused, thereby improving the overall efficiency of the system. Installing an efficient heat exchanger can transfer the heat in the syngas to other process links, such as preheating the feed or generating steam. The design of the heat exchanger should ensure maximum heat transfer efficiency and adapt to the operating conditions of the gasifier. In the process of using steam as a gasifying agent, the management and utilization of steam is a key link. Steam not only participates in the gasification reaction, but also carries a large amount of heat energy. How to efficiently utilize this part of heat energy has a significant impact on the efficiency of the overall system. The mixing ratio of steam and syngas in the gasification process needs to be precisely controlled. Too much or too little steam will affect the efficiency of the gasification reaction. Therefore, controlling the supply of steam is crucial to optimizing the gasification process. The use of steam in the gasification process is not limited to the reaction zone, but can also be reused through the waste heat recovery system, such as for other industrial processes or directly for power generation. Modern biomass gasification systems are usually equipped with automated control systems that can monitor and adjust the heat energy in the gasification process in real time. This intelligent heat energy management can significantly improve the operating efficiency of the system. Heat loss is one of the main factors that reduce the efficiency of the gasification system. During the heat transfer process, reasonable insulation design and maintenance measures can significantly reduce the ineffective loss of heat, thereby improving the overall energy efficiency of the system. Selecting efficient insulation materials and maintaining them regularly can effectively reduce heat loss in the furnace and pipelines. Especially in the high-temperature gasification reaction zone, high-quality insulation materials can ensure that heat is concentrated in the reaction zone, thereby improving reaction efficiency. In the thermal energy management of biomass gasifiers, the optimization of heat distribution and utilization is the core to ensure efficient and economical operation of the system. The overall performance of the gasification system can be significantly improved by rationally designing the heat distribution path, effectively recovering and reusing waste heat, efficiently managing steam, applying intelligent control systems, and reducing heat losses. This not only improves energy utilization, but also reduces operating costs, laying the foundation for the widespread application and sustainable development of biomass gasification technology.
Gas boilers are widely used in industrial, commercial and residential heating fields. Their combustion efficiency directly affects energy utilization, operating costs and environmental pollution levels. The improvement of combustion efficiency depends not only on the design and operation of the boiler, but also on the purity of the fuel used. Fuel purity plays a key role in ensuring the efficient, safe and environmentally friendly operation of gas boilers. This article will discuss in detail the requirements of fuel purity for the combustion efficiency of gas boilers, covering aspects such as sulfur content, impurity content, moisture content and methane content in the fuel. Sulfide in the fuel will generate sulfur dioxide (SO₂) during combustion. Sulfur dioxide combines with water vapor to form sulfuric acid, which causes serious corrosion to metal parts inside the boiler. In addition, sulfur dioxide is one of the main causes of acid rain, which has adverse effects on the environment and human health. Sulfide can also lead to incomplete combustion and carbon deposition, further reducing combustion efficiency. In order to improve combustion efficiency and extend boiler life, the sulfur content in the gas should be as low as possible. Generally, the standard for sulfur content in natural gas is below 5 ppm (parts per million). Low sulfur content can significantly reduce the generation of acidic gas, reduce the risk of corrosion, and reduce pollutant emissions, meeting strict environmental protection requirements. Impurities in the fuel (such as dust, heavy metals, sulfides, nitrides, etc.) will form incombustible residues or carbon deposits during the combustion process, blocking the burner and heat exchanger, and hindering the effective transfer of heat. This not only reduces the combustion efficiency, but also may cause overheating, damage or reduced efficiency of the boiler. In addition, the presence of impurities will increase the wear of the equipment and increase maintenance costs. High-purity natural gas should have a very low impurity content, which should generally be kept at an extremely low level to ensure clean and complete combustion. The use of high-quality fuel can reduce the maintenance requirements of the equipment and extend the service life of the boiler while maintaining high thermal efficiency and stability. The moisture in the fuel will absorb a lot of heat for evaporation during the combustion process, which will significantly reduce the actual calorific value of the fuel and reduce the thermal efficiency of the boiler. Fuel with high moisture content not only increases energy consumption, but may also lead to incomplete combustion, produce more unburned substances, and affect the environment. In addition, the moisture in the fuel may condense inside the boiler, causing corrosion or scaling, further affecting the performance and life of the equipment. The moisture content in the fuel gas should be as low as possible, ideally less than 100 ppm. Keeping the moisture content low can increase the effective calorific value of the fuel, ensure a more efficient combustion process, and reduce the risk of corrosion and scaling inside the boiler. Generally speaking, the methane content in natural gas should reach more than 85% to ensure high calorific value and high combustion efficiency. Fuels with lower methane content may require higher fuel volumes to achieve the same heat output, which will reduce the overall efficiency of the system and increase operating costs. The purity of the fuel directly affects the completeness of combustion. High-purity fuels can fully react with oxygen during the combustion process to produce complete combustion products such as carbon dioxide and water, thereby converting as much chemical energy in the fuel into heat energy as possible. Low-purity fuel may contain a large amount of non-combustible impurities, resulting in incomplete combustion, carbon monoxide, soot and other unburned substances, which not only wastes fuel but also increases the difficulty of equipment maintenance. Thermal efficiency is an important performance indicator of gas boilers, representing the ability of the boiler to convert the chemical energy of the fuel into thermal energy. Using high-purity fuel can reduce the deposition of non-combustible substances and the pollution of heat exchange surfaces, ensuring that heat can be efficiently transferred to the medium that needs to be heated. Fuels with low impurity content can reduce the frequency of equipment cleaning and maintenance, so that the boiler can maintain efficient operation for a longer time. The emissions of gas boilers mainly include carbon dioxide, water vapor and a small amount of nitrogen oxides (NOx). High fuel purity means fewer harmful emissions generated during the combustion process. In particular, low-sulfur fuel can significantly reduce sulfur dioxide emissions and reduce the risk of acid rain and air pollution. Fuels with high methane content help reduce the generation of unburned substances and further reduce negative impacts on the environment. Using high-purity fuel can not only improve combustion efficiency, but also extend the service life of gas boilers. Low-sulfur, low-impurity fuels reduce corrosion and wear of boiler internal components, reduce carbon and coking, and reduce dirt deposition on heat exchange surfaces. These factors work together to reduce boiler maintenance requirements and extend equipment life, thereby reducing operating costs. In order to meet fuel purity requirements, fuels can be pretreated before use. For example, impurities and moisture in natural gas can be removed through processes such as desulfurization, dehydration, and filtration. Desulfurization equipment can effectively reduce the sulfur content in natural gas and avoid the formation of acidic gases. Drying equipment can reduce the moisture content of fuel and ensure the high calorific value of fuel. In addition, filters can remove solid particles from fuel and reduce the formation of carbon deposits during combustion. Fuel purity has a vital impact on the combustion efficiency of gas boilers. High-purity fuel can not only improve the thermal efficiency of the boiler, but also extend the service life of the equipment, reduce maintenance costs, and significantly reduce environmental pollution. In order to achieve the best performance of the gas boiler, the sulfur content, impurity content, moisture content and methane content in the fuel must be strictly controlled. Through fuel pretreatment, selection of high-quality fuel suppliers and strengthening of fuel system monitoring and maintenance, the high purity of the fuel can be effectively ensured, thereby achieving efficient, safe and environmentally friendly operation of the boiler.
A 12-tonne biomass gasifier of Guangdong Baojie was successfully installed in Malaysia and will be put into use in the near future, which will save the customer's enterprise nearly ten million production costs a year. Prior to the 1970s, Malaysia's economy maintained high growth rates and neglected environmental management, resulting in serious environmental pollution in Malaysia. In order to curb further environmental degradation, the Malaysian government introduced a series of environmental protection measures, restricting excessive deforestation and tightening controls on industrial emissions. Malaysia does not produce much coal, but it relies mainly on thermal power generation, and the annual growth in electricity consumption makes Malaysia very dependent on coal imported from Indonesia. In recent years, Indonesia has reduced the amount of coal exported and the price of coal has risen, which has directly led to an increase in production costs for companies opening factories in Malaysia. Nowadays, factories in Malaysia are in dire need of a clean, low-polluting, inexpensive, and abundant source of new energy. Malaysia has 18.31 million hectares of forests, with forest coverage of about 55.8%, The developed wood processing industry is a large amount of forestry waste, that can be used as raw materials for biomass gasifiers. Biomass energy generally refers to biomass energy, biomass energy is the energy provided by living plants in nature, these plants use biomass as a medium to store solar energy, which is a renewable energy source. The feedstock for biomass gasifiers can be wood chips, wood flakes, wood flour, as well as waste building formwork and agricultural waste straw. In the past, Malaysian factories and domestic biomass gasifier manufacturers and corporations, purchased 1 tonne - 4 tonnes of small biomass gasifiers, with the growth of the factory, the price of coal and natural gas rose. Customers need biomass gasifiers with larger steam production capacity to replace coal and natural gas. The biomass gasifier produced by Guangdong Baojie, the largest tonnage of biomass gasifier full load single steam production can reach 35t / h. And can do three months full load without stopping the furnace, takes a long time to run at the same time, no tar, does not clog the pipe, no need to clean ash. It eliminates the trouble of traveling back and forth between two countries because of product quality problems. In terms of environmental protection, Guangdong Baojie's biomass gasifier has a boiler tail gas emission below 20mg/m³ in domestic actual projects. In terms of operation, Guangdong Baojie has 160+ projects in operation in China, all of which can be visited on-site. The success of this project proves that the biomass gasifier produced by Guangdong Baojie is of high quality, and we will have in-depth cooperation with overseas customers in the future.
1、R&D AdvantageWe have our own technology research and development team, including 7 senior engineers, 11 engineers, 58 workshop technicians and production staff, 22 energy management teams, and 43 project construction and after-sales teams. Domestic and foreign well-known South China University of Technology, Guangdong University of Technology, and other authoritative colleges and universities have cooperated with our company, in-depth development of gasification technology mining and product updates.2、Production AdvantageOur company has its own production factories, the products are self-produced and self-marketed, and there is no generation of production and processing links. Product quality is guaranteed.3、Product quality advantageMore than 80% of the whole set of equipment of the Baojie gasifier is made of high-temperature resistant stainless steel, and all motors are made of stainless steel, so the equipment has a long service life and the product quality is guaranteed.4、Industry advantages1. The largest tonnage of gasification equipment. Now on the market, the tonnage of gasifier is mainly concentrated in the following 10 tonnes, our biomass gasifier, a single unit up to 30 tonnes! And has been in operation for more than 2 years, far ahead of peers. It is the largest producer, manufacturer, and operator of gasifier tonnage in the same industry.2. Run the projects. Our company was established in 2013, there have been 83 sets of gasifier heating projects put into operation, of which there are 48 sets of 10 tonnes to 20 tonnes of gasifiers, 32 sets of 20 tonne of gasifiers, 2 sets of 25 tonnes, 1 set of 30 tonnes. Nowadays, large group companies such as Maklang Food, Sanhe Pipe and Pile, and Yangtze River Three Gorges Group are using our gasification equipment.3. The longest running time. Many gasifiers on the market will have tar junctions and clogging pipes. Need to stop the furnace for maintenance, our gasifier can run continuously for 90 days without stopping the furnace, equipment operation is stable, safe, and reliable.5、Management experience advantageThere are nearly 30 projects contracted by our company, and we have a large operation and management team with rich operation and management experience.6、Market Development AdvantageOur business scope covers Guangdong, Fujian, Zhejiang, Jiangsu, Jiangxi, Shandong, Hubei, Anhui, Shaanxi, Shanxi, and other provinces, and we have many dealers and fuel suppliers all over the country with rich experience in market development.7、Technical Advantages1. Baojie has the core technology of gasification technology and invention patents. Among them, there are 7 invention patents, 21 utility model patents, and appearance patents.2. The Baojie gasifier belongs to the upper suction type medium-low temperature gasifier, the gas temperature is constant between 60-80 degrees, the gas temperature is low, and the equipment runs safely and stably.3. During normal production, the wall surface temperature of all equipment of the gasifier is less than 80℃, which makes the equipment safe.4. The Baojie gasifier has a high degree of automation, feeding, slag discharge, etc. can be automated, without manual operation.5. Baojie gasifier has the technology and patent invention of tar treatment, tar is directly treated, with no external discharge. There will be no dirty and messy situation at the site.8. Advantage of control systemBaojie biomass gasifier has a high degree of automation and is controlled by a PLC centralized control system. With an automated control system and manual 2 sets of control systems, safety is guaranteed.9、Environmental protection advantageMany gasifiers on the market need to install bag dust removal equipment, Baojie gasifiers do not need bag dust removal equipment, and particulate emissions can reach the local natural gas emission standards.
A 12-ton biomass gasifier of Guangdong Baojie was successfully installed in Malaysia and will be put into use in the near future, which will save nearly ten million production costs for the customer's enterprise in a year.Before the 1970s, Malaysia's economy maintained high growth, ignoring environmental governance, resulting in serious environmental pollution in Malaysia, in order to curb further environmental degradation, the Malaysian government introduced a series of environmental protection measures to limit excessive deforestation, strengthened the control of industrial emissions.Malaysia does not produce much coal, but it relies mainly on thermal power generation, and the annual growth in power consumption makes Malaysia very dependent on coal imported from Indonesia. In recent years, Indonesia has reduced the amount of coal exported and the price of coal has risen, which has directly led to an increase in production costs for companies that have opened factories in Malaysia.Nowadays, factories in Malaysia are in dire need of a clean, low-polluting, inexpensive and abundant source of new energy.Malaysia has 18.31 million hectares of forests, forest coverage of about 55.8%, the developed wood processing industry is a large amount of forestry waste, can be used as raw materials for biomass gasifier. Biomass energy generally refers to biomass energy, biomass energy is the energy provided by living plants in nature, these plants use biomass as a medium to store solar energy, which is a renewable energy source.The feedstock for biomass gasifier can be wood chips, wood flakes, wood flour, or waste construction formwork and agricultural waste straw. In the past, Malaysian factories and domestic biomass gasifier manufacturers and cooperation, the purchase of 1 ton - 4 tons of small biomass gasifier, with the growth of the factory, coal and natural gas prices. Customers need to produce more steam biomass gasifier to replace coal and natural gas.The biomass gasifier produced by Guangdong Baojie, the largest tonnage of biomass gasifier full load single steam production can reach 35t / h. And can do three months full load without stopping the furnace, a long time to run at the same time, no tar, do not clog the pipe, no need to clean ash. It eliminates the trouble of going back and forth between two countries for many times because of product quality problems. In terms of environmental protection, Guangdong Baojie's biomass gasifier has a boiler tail gas emission below 20mg/m³ in domestic actual projects. In terms of operation and management, Guangdong Baojie has 160+ projects in operation in China, all of which can be inspected on site.
Guangdong Baojie Environmental Technology's biomass gasifier saves energy costs for Anhui papermaking enterprises and helps them transform into green energy companies.
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