The global plastic pollution control has entered a dual upgrading stage of policy rigidity constraints and technological innovation driven. EU Packaging and Packaging Waste Regulations(
PPWR will be fully implemented in August 2026, with a series of policies such as the US National Plastic Pollution Strategy and China's Action Plan for Plastic Pollution Control (2026-2030) being implemented intensively, explicitly requiring the achievement of environmental protection standards for disposable and industrial plastic packaging throughout its entire lifecycle before 2030. Polyethylene (PE) protective film, as a core functional material in the global industrial protection, consumer electronics, new energy, and logistics packaging fields, has an annual demand of over 6.5 million tons. Its degradation performance and environmental adaptability have become the core threshold for industry compliance access. Luoyang Lvzhihui Plastic Degradation Technology Co., Ltd. relies on its independently developed AdmPro ® The anaerobic biodegradation technology platform, after more than ten years of technological breakthroughs and pilot testing, has successfully developed and launched PE3000 anaerobic biodegradation
masterbatchThis product can accurately adapt to the existing processing system of PE protective film, achieving complete mineralization in three major scenarios: anaerobic degradation in landfills, soil burial degradation, and seawater anaerobic layer degradation. The degradation cycle can accurately match the full life cycle requirements of PE protective film for 1-3 years, providing a systematic technical solution that combines innovation, industrial adaptability, and environmental feasibility for the green transformation of the global PE protective film industry, filling the technical gap of anaerobic biodegradation of PE materials in all scenarios.
1、 Global plastic restriction policy iteration andPEThe dual challenges of the protective film industry
(1) Global plastic restriction policy: rigid upgrade from category ban to full lifecycle control
In 2026, the global plastic restriction policy has completed a fundamental transformation from "initiative guidance" to "regulatory enforcement", forming a regulatory system covering the entire production, circulation, use, and disposal chain, and forming a triple rigid constraint on the PE protective film industry, promoting the industry to enter a new stage of development where "compliance is survival".
One is the policy coverage of the whole region.As of the first quarter of 2026, 78 countries and regions around the world have introduced industrial plastic packaging control policies, among which 32 developed countries such as the European Union, the United States, and Japan have implemented a dual regulatory model of "ban and control+mandatory degradation" for PE protective films. The EU PPWR stipulates that from 2028 onwards, all industrial PE packaging must be certified, and products that do not meet the standards are strictly prohibited from entering the EU market for circulation. At the same time, it is clear that enterprises must bear the main responsibility for the recycling and disposal of packaging waste; The California SB 54 Act transfers the responsibility for packaging waste management to production companies, explicitly requiring that the biodegradation rate of PE protective film in landfill environments must be ≥ 90% within 36 months. Companies that fail to meet the standard will face high administrative penalties; The action plan for plastic pollution control in China has included PE protective film in the key control list, requiring all production enterprises to complete the full life cycle environmental protection assessment of their products before 2027. Enterprises that fail to meet the standards will have their production licenses revoked in accordance with the law and be prohibited from carrying out production and business activities.
The second is the standardization of requirements.The international standard system has established clear quantitative indicators for the degradation and safety performance of PE protective films, and has built a comprehensive and multi-level testing system. Among them, ISO 15985 and ASTM D5511 clearly stipulate that the biodegradation rate of PE protective film in anaerobic landfill environment must be ≥ 90% after 36 months; ASTM D6691 specifies that for seawater environments, the degradation rate of PE materials in the anaerobic layer of seawater must be ≥ 80% after 36 months. At the same time, various standards have added mandatory testing items such as microplastic residue, degradation product toxicity, and heavy metal migration. Traditional non degradable PE protective films can no longer meet global compliance requirements and face the risk of market elimination.
The third is the strict implementation of supervision.The European Union has established an "Environmental Traceability System for Plastic Packaging" and implemented mandatory spot checks on imported PE protective films, with a sampling ratio of no less than 30%. Unqualified products will be prohibited from entering the country and fined 10% -30% of their value. At the same time, relevant enterprises will be included in the credit blacklist; The US FDA has included the degradation performance of PE protective film in the scope of regular sampling, and relevant enterprises have been ordered to stop production and rectify according to law, with a deadline to complete technical upgrades. Under multiple policy pressures, the green transformation of the PE protective film industry has shifted from an "optional action" to a "mandatory action", and technological innovation has become the core competitiveness for the survival and development of enterprises.
(II)PEProtective film industry: sharp contradiction between trillion dollar market and environmental crisis
PE protective film is widely used in various fields such as consumer electronics, new energy photovoltaics, automotive manufacturing, logistics packaging, and building material protection due to its excellent flexibility, weather resistance, controllable peeling, and cost advantages. It is an indispensable functional material in modern industrial systems. With the continuous expansion of industrial scale, the pressure of environmental governance is becoming increasingly prominent.
According to data, by 2025, the global market size of PE protective film will reach 18.2 billion US dollars, with China's market size of 8.2 billion US dollars, accounting for 45.1% of the global market share and becoming the world's largest producer and consumer of PE protective film; The global annual demand is 6.58 million tons, and China's annual demand is 2.96 million tons, with compound annual growth rates of 8.6% and 8.7% respectively. It is expected that by 2030, the global annual demand will exceed 9 million tons, and the market size is expected to reach 32 billion US dollars. From the perspective of application structure, the consumer electronics field accounts for 32%, mainly used for screen and shell protection of products such as mobile phones, tablets, laptops, etc; The new energy photovoltaic field accounts for 28%, used for photovoltaic module packaging and frame protection; The automotive manufacturing sector accounts for 18%, used for interior, paint, and component protection; The logistics and building materials sector accounts for 22%, mainly consisting of stretch wrap film and surface protective film for building materials.
From the perspective of product lifecycle, the usage period of PE protective film is strictly limited to 1-3 years, with a production cycle of ≤ 1 month, a storage period of ≤ 6 months, and an actual usage period of 1-2.5 years. After disposal, environmental disposal must be completed within 3 years, otherwise it will cause long-term environmental pollution. However, traditional PE protective films are composed of saturated C-C long chains, with stable molecular structures and a lack of recognizable degradation sites by microorganisms. They are difficult to be metabolized and decomposed by microorganisms in natural environments, with a natural degradation cycle of 200-500 years. A large amount of discarded PE protective films have become one of the main sources of "white pollution".
According to the Global Plastic Pollution Status Report released by the United Nations Environment Programme (UNEP) in 2026, approximately 1.65 million tons of discarded PE protective film enter the natural environment worldwide each year, with 45% going to landfills, 30% scattered in soil environments, and 25% flowing into the ocean. In landfills, PE protective film occupies the landfill space for a long time, hindering the infiltration of leachate and the diffusion of landfill gas. At the same time, it slowly releases microplastics under the action of microorganisms, polluting groundwater and surrounding soil; In the soil environment, fragments of PE protective film damage the soil aggregate structure, hinder crop root growth and nutrient absorption, reduce soil fertility, and long-term accumulation can lead to soil degradation, affecting agricultural production; In the marine environment, PE protective film is decomposed into microplastics by UV irradiation and wave impact. After being ingested by marine organisms, it accumulates through the food chain and ultimately endangers human health, causing irreversible damage to the marine ecosystem.
The traditional disposal methods of PE protective films have fatal shortcomings and cannot achieve a balance between environmental protection and efficiency. During the mechanical recycling process, the mechanical properties of PE protective film are severely degraded, and the recycled materials can only be used for low value-added products. The global recycling rate of PE protective film is less than 12%; Chemical recycling needs to be carried out under high temperature and high pressure conditions, with high energy consumption, large carbon emissions, and the production of toxic by-products such as benzene derivatives and formaldehyde during the reaction process, which poses a risk of secondary pollution; Burning disposal can release carcinogenic substances such as dioxins and polycyclic aromatic hydrocarbons, causing air pollution; Conventional landfill cannot solve the long-term residual problem of PE protective film, forming permanent environmental hazards. In this context, the PE protective film industry is facing the development paradox of "the faster the market expansion, the more severe the pollution", and urgently needs a degradation technology solution that adapts to the entire product lifecycle and combines compliance and economy.
(3) Existing degradation technologies: lack of adaptability and core bottleneck of industrial transformation
The current global degradable PE material technology is mainly divided into two categories: fully biodegradable materials and additive degradable masterbatch. Both types of technologies have obvious shortcomings and cannot adapt to the production process and performance requirements of the PE protective film industry. They have become the core bottleneck of the industry's green transformation.
Fully biodegradable materials (such as
PLA、 Although PBAT, PBS, etc. can achieve complete biodegradation and meet global plastic restriction policy requirements, their compatibility with PE materials is extremely poor and cannot be directly blended and processed with PE raw materials. If an enterprise uses this type of material to produce PE protective film, it needs to comprehensively renovate the existing blown film and cast film production lines, adjust core process parameters such as screw speed, extrusion temperature, blown film pressure, etc. The cost of renovating a single production line is high, which is difficult for small and medium-sized enterprises to afford. At the same time, the mechanical properties and weather resistance of fully biodegradable materials cannot meet industrial protection requirements. For example, PE protective films for photovoltaic modules need to have excellent UV resistance and high and low temperature resistance, and PE protective films for automotive paint surfaces need to have stable peeling force. However, fully biodegradable materials have obvious shortcomings in these performance aspects. In addition, the cost of fully biodegradable materials is 35% -100% higher than traditional PE materials, significantly increasing product prices and reducing market competitiveness for enterprises, making it difficult to achieve large-scale industrial applications.
Traditional additive degradation masterbatch mainly relies on photodegradation and oxidative degradation mechanisms, and its degradation process is greatly limited by environmental conditions. It can only achieve partial degradation in specific environments such as strong light and high temperature, and cannot cover the main waste scenarios of PE protective films such as landfills (anaerobic), deep soil layers (facultative/anaerobic), and seawater anaerobic layers. At the same time, the degradation cycle of such masterbatch is uncontrollable, which can easily lead to problems such as "premature degradation during use" (affecting product protection function) or "slow degradation after disposal" (unable to meet the requirements of plastic limit policies). More importantly, traditional additive degradation masterbatch is prone to producing small molecule toxic intermediate products during the degradation process, posing a risk of secondary pollution, and has not been certified by international authoritative standards such as ISO and ASTM, which cannot help enterprises break through international trade green barriers.
The emergence of Green Hub PE3000 anaerobic biodegradation masterbatch has accurately addressed the core shortcomings of existing technology, achieving the unity of four core goals: degradation performance, industry adaptation, cost control, and lifecycle fit. It provides key technical support for the green transformation of the PE protective film industry and promotes the industry's transition from "passive compliance" to "active green".
IIPE3000Anaerobic biodegradation masterbatch: core technology innovation and degradation mechanism analysis
(1) Product positioning and core technological advantages
PE3000 anaerobic biodegradation masterbatch is based on the independently developed AdmPro by Green Hub ® The anaerobic biodegradation technology platform is a specialized degradation masterbatch developed specifically for PE protective films and other PE products. Its core positioning is "not changing the nature of PE materials, not affecting product protection performance, controllable degradation in all scenarios, and low-cost compliance transformation". This product uses food grade high-density polyethylene (HDPE) as the carrier and has excellent compatibility with commonly used PE protective film materials such as LLDPE (linear low-density polyethylene), LDPE (low-density polyethylene), HDPE, etc. The addition ratio is only 1% -2%, which can implant controllable anaerobic biodegradation function into PE material and achieve complete biodegradation in three major scenarios: landfill, soil, and seawater.
Compared with existing degradation technologies, PE3000 anaerobic biodegradation masterbatch has three core technological advantages, highlighting technological innovation and industrial practicality:
Firstly, the degradation mechanism is advanced. This product breaks through the limitations of traditional single degradation pathways and adopts a dual synergistic degradation mechanism of "microbial activation+molecular chain catalysis". It can achieve complete mineralization of PE materials in anaerobic environments without any residual microplastics or toxic intermediates, and its degradation performance reaches the international leading level.
Secondly, it has strong industrial adaptability. This product can be adapted to existing PE protective film blowing, casting, and coating production lines with zero modification, without the need to adjust process parameters or replace molds. It can be directly integrated into the existing production system without affecting the core properties of the product such as tensile strength, peel strength, haze, and weather resistance, ensuring the production efficiency and product quality of the enterprise.
The third is the prominent cost-effectiveness. The low addition ratio of 1% -2% limits the overall cost increase of PE protective film, which is much lower than the cost increase of 35% -100% for fully biodegradable materials. This significantly reduces the cost of green transformation for enterprises and has the conditions for large-scale industrial application, which can quickly promote the compliance upgrade of the entire industry.
(2) Dual synergistic degradation mechanism: complete closed-loop from molecular fracture to complete mineralization
The core innovation of PE3000 anaerobic biodegradation masterbatch lies in the construction of a dual synergistic degradation mechanism of "molecular chain catalytic breakage+microbial anaerobic metabolism". The entire degradation process is divided into four consecutive stages, forming a complete closed loop of "polymer chain breakage small molecule metabolism complete mineralization", achieving harmless degradation and resource recycling of PE protective film. The specific degradation process is as follows:
The first stage is the biological attachment and activation stage (lasting 1-3 months). When the PE protective film with PE3000 masterbatch is discarded, it enters anaerobic environments such as landfills, deep soil layers, and seawater anaerobic layers. The microbial activation factors added to the masterbatch (mainly natural biological surfactants and microbial attractants) are quickly released, attracting anaerobic microorganisms such as methanogens, clostridia, pseudomonas, and actinomycetes from the environment to colonize on the surface of the PE protective film, forming a dense biofilm. Anaerobic microorganisms in biofilms secrete extracellular oxidases and hydrolases, activating the catalytic system in the mother granules and officially initiating the degradation process. This stage is mainly the preliminary preparation for the degradation process, and the duration depends on the environmental temperature, humidity, and microbial content, usually 1-3 months.
The second stage is the molecular chain catalytic cleavage stage (lasting 6-12 months). The new transition metal complex catalyst in the masterbatch undergoes redox reactions under the action of enzymes secreted by anaerobic microorganisms, accurately inserting into the C-C bond of the PE molecular chain, reducing the activation energy of the molecular chain, breaking the stability of saturated C-C long chains, and catalyzing the breakage of high molecular weight PE (usually with a molecular weight of 10 ⁵ -10 ⁶) into low molecular weight oligomers (molecular weight<10 ⁴), dimers and monomers (mainly ethylene and propylene monomers), achieving the key transformation from "difficult to degrade macromolecules" to "metabolically small molecules". This stage is the core link of the degradation process, and the efficiency of molecular chain breakage is affected by the addition ratio of PE3000 and environmental conditions. The higher the addition ratio, the faster the molecular chain breakage rate and the shorter the degradation cycle.
The third stage is the anaerobic metabolism stage of microorganisms (lasting 12-24 months). After catalytic cleavage, low molecular weight PE fragments (oligomers, dimers, and monomers) are actively transported into cells by anaerobic microorganisms in biofilms as carbon and energy sources, and undergo decomposition and metabolism through metabolic pathways such as β - oxidation and tricarboxylic acid cycle. Among them, a part of the carbon element is converted into microbial biomass for microbial growth and reproduction; The other part is converted into carbon dioxide (CO ₂) and methane (CH ₄), of which methane can be collected through the landfill biogas recovery system for clean energy utilization, achieving resource recycling and improving environmental benefits.
The fourth stage is the complete mineralization and humification stage (lasting 6-12 months). The intermediate products produced by microbial metabolism are further decomposed and ultimately converted into inorganic minerals (such as calcium carbonate, silica), water (H ₂ O), and organic humus. Among them, organic humus can combine with minerals in the soil, improve soil particle structure, enhance soil fertility, and promote plant growth; The marine biomass generated in the seawater environment can be utilized by marine plankton and integrated into the marine ecological cycle. The entire degradation process has no residual microplastics or toxic intermediates (such as formaldehyde and benzene), achieving an ecological cycle of PE protective film "coming from nature and going back to nature".
(3) Core technical parameters and authoritative certification: compliant with global plastic limit standards
PE3000 anaerobic biodegradation masterbatch has been comprehensively tested by international authoritative testing institutions such as Intertek, SGS, BV, etc. The core technical parameters comply with global mainstream environmental standards and plastic limit policies such as ISO, ASTM, GB, etc. The degradation performance of the three major scenarios has reached the industry-leading level. The specific testing indicators are shown in the table below:
Note: 1. The degradation cycle is the detection value under standard anaerobic environment. In actual environment, the degradation cycle may fluctuate slightly according to factors such as temperature, humidity, and microbial content; 2. The biodegradation rate is determined by a combination of weight loss method and chromatographic analysis method to ensure the accuracy and reliability of the detection results; 3. Microplastic residues were detected using laser particle size analysis with a detection accuracy of 0.1 μ m, and no microplastic residues were detected.
In addition, the food contact safety of PE3000 anaerobic biodegradable masterbatch has been certified by Chinese GB 4806.7-2023, US FDA and other standards. The content of heavy metals (lead, cadmium, mercury, chromium, etc.) is less than 0.1mg/kg, and there is no migration of harmful substances such as plasticizers, bisphenol A, phthalates, etc., fully meeting the safety requirements of PE protective film for food contact. At the same time, it can be widely used in fields with high safety requirements such as medical device packaging and hygiene product packaging.
3、 Lifecycle compatibility: precise matchingPEresist film1-3Annual full lifecycle
(1) Usage cycle: Degradation factor dormancy, ensuring protective function
The full life cycle of PE protective film is divided into four stages: production, storage, use, and disposal. The production cycle is ≤ 1 month, the storage period is ≤ 6 months, and the actual use period is 1-2.5 years. After disposal, environmental disposal must be completed within 3 years. The entire life cycle is strictly limited to 1-3 years. The core design concept of PE3000 anaerobic biodegradation masterbatch is to achieve a precise balance of "stable use period and rapid degradation after disposal", ensuring that the product can be quickly absorbed by the environment after completing its protective function, and reducing plastic pollution from the source.
The degradation factors (microbial activation factors and catalysts) in PE3000 masterbatch are environmentally responsive and are only activated by anaerobic microorganisms in anaerobic environments (landfill sites, deep soil layers, and anaerobic layers of seawater), initiating the degradation process. In the storage and use scenarios of PE protective film (room temperature, aerobic), the degradation factor is in a dormant state, does not participate in any chemical reactions, does not affect the mechanical properties, protective properties, and service life of the product, and can ensure that the product remains stable for 1-3 years of use, perfectly matching the life cycle characteristics of PE protective film.
(2) Waste degradation cycle: precise regulation, in line with environmental consumption needs
The degradation cycle of PE3000 anaerobic biodegradation masterbatch can be flexibly controlled by adding ratios, which can accurately match the full lifecycle management goal of PE protective film for 1-3 years, avoiding the pain points of traditional degradation materials such as "premature degradation during use" or "slow degradation after disposal". Specifically, according to the addition ratio of PE3000 masterbatch, the degradation cycle can be regulated as follows:
When the addition ratio is 1%, the degradation cycle of PE protective film in landfill (anaerobic environment) is about 36 months, the degradation cycle in soil burial environment is about 60 months, and the degradation cycle in seawater anaerobic layer is about 90 months. It is suitable for PE protective films with longer service life (2-3 years), such as protective films for photovoltaic modules and building materials;
When the addition ratio is 2%, the degradation cycle of PE protective film in landfills is shortened to 24 months, soil burial degradation cycle is shortened to 48 months, and seawater anaerobic layer degradation cycle is shortened to 72 months. It is suitable for PE protective films with shorter service life (1-2 years), such as consumer electronics protective film and temporary automotive protective film.
This controllable degradation characteristic enables PE3000 masterbatch to adapt to PE protective film products with different usage cycles, ensuring that the product can quickly degrade in the natural environment after completing its functional use, achieving environmental absorption. It not only meets the requirements of global plastic restriction policies for degradation cycles, but also ensures the performance of the product, achieving the unity of compliance and practicality.
(3) Environmental benefits throughout the entire lifecycle: achieving low-carbon environmental protection and resource recycling
The PE protective film using PE3000 anaerobic biodegradable masterbatch has achieved harmless treatment throughout the entire life cycle from "production use waste degradation return", with significant environmental benefits. It can effectively reduce plastic pollution, help achieve the global "dual carbon" goal, and promote the transformation of the industry towards a circular economy.
In the production stage, PE3000 masterbatch can be directly blended and processed with PE raw materials, using the traditional production process of PE protective film without the need for additional energy consuming equipment. The energy consumption and carbon emissions during the production process are basically the same as those of traditional PE protective film, without additional carbon emissions, achieving "low-carbon production"; During use, PE3000 masterbatch does not have any harmful substance migration, which not only ensures the quality and safety of the protected products, but also reduces the loss of protected items such as food and electronic products, indirectly achieving low-carbon environmental protection; In the disposal stage, the PE protective film is completely degraded in three major scenarios, without any microplastic residue or toxic intermediate products, avoiding the damage of "white pollution" to soil, groundwater, and marine environment, and protecting the balance of the ecosystem; In the degradation stage, the methane generated during the degradation process can be collected through the landfill biogas recovery system and used as a clean energy source to achieve resource recycling. At the same time, the generated humus can improve soil structure and enhance soil fertility, achieving the goal of "turning waste into treasure".
According to calculations by the Chinese Academy of Environmental Sciences, for every 10000 tons of PE protective film with PE3000 masterbatch added, approximately 12000 square meters of landfill land is saved; Reduce approximately 8000 tons of microplastic pollution and effectively protect the soil and marine ecological environment. With the large-scale promotion and application of PE3000 masterbatch, its environmental benefits will be further highlighted, providing strong support for global plastic pollution control and the achievement of the "dual carbon" goal.
4、 Market application and industrial value: leading the worldPEGreen transformation of protective film
(1) Application scenario: CoveragePEProtective film for all fields, adapted to global market demand
PE3000 anaerobic biodegradation masterbatch, with excellent degradation performance, industrial adaptability, and safety performance, can be widely used in various PE protective film products, covering multiple fields such as consumer electronics, new energy, automobiles, logistics, and building materials, and adapting to plastic restriction policies and market demands in different countries and regions around the world. The specific application scenarios are as follows:
1. In the field of consumer electronics: mainly used as screen protectors and shell protectors for mobile phones, tablets, laptops, smartwatches and other products, meeting the requirements of high transparency, scratch resistance, biodegradability, and no harmful substance migration, and adapting to the environmental compliance needs of high-end consumer electronics markets such as the European Union and the United States;
2. In the field of new energy: used for photovoltaic module packaging film, frame protection film, power battery protection film, energy storage equipment packaging film, with excellent weather resistance, insulation and degradability, suitable for the green development needs of the new energy industry, and helping the photovoltaic and energy storage fields achieve low-carbon transformation of the entire industry chain;
3. In the automotive field: used for automotive paint protection film, interior protection film, component packaging film, temporary protection film, with controllable peeling force, without damaging the automotive paint and interior, while meeting the global automotive industry's green packaging compliance requirements, helping the automotive industry achieve "plastic reduction and carbon reduction";
4. In the field of logistics and building materials: used for stretch wrap film, building material surface protective film, home appliance packaging film, furniture protective film, with high strength, high toughness and degradability, reducing plastic waste pollution in the logistics and building materials field, and adapting to the green transformation needs of industrial packaging;
5. Export specific fields: Specially adapted to countries and regions with strict plastic restriction policies such as the European Union, the United States, Japan, and South Korea, it can help enterprises quickly obtain local environmental certifications, break through green trade barriers, enhance product international competitiveness, and expand international markets.
At present, Green Hub PE3000 anaerobic biodegradation masterbatch has reached deep cooperation with multiple domestic PE protective film production enterprises. The products are widely used in consumer electronics, new energy, automobiles and other fields, and exported to countries and regions such as the European Union, the United States, and Southeast Asia. The market feedback is good and has been widely recognized by enterprises in the industry.
(2) Industry Value: Cracking Industry Pain Points and ReshapingPEPattern of protective film industry
The promotion and application of PE3000 anaerobic biodegradation masterbatch not only provides a compliant transformation technical solution for the PE protective film industry, but also promotes the industry to achieve technological, ecological, and economic upgrades. It has important industrial and social value, mainly reflected in four aspects:
One is the compliance value, which helps enterprises break through policy barriers. PE3000 masterbatch can help PE protective film companies quickly meet the requirements of the global plastic restriction policy. Through various environmental certifications such as ASTM D5511, ISO15985, GBT33797, etc., it ensures the compliant circulation of products in the global market, avoids risks such as production stoppage, fines, and market exit due to compliance issues, and guarantees the sustainable development of enterprises.
The second is the technological value, which drives China's degradation technology to lead the world. The dual synergistic degradation mechanism of "microbial activation+molecular chain catalysis" of PE3000 masterbatch fills the technical gap of anaerobic biodegradation of PE materials in all scenarios, and promotes the leap of China's plastic degradation technology from "following" to "leading". The relevant technology has obtained multiple patents, providing Chinese technology solutions for the global green transformation of PE packaging.
The third is ecological value, which helps global plastic pollution control. The promotion and application of PE3000 masterbatch has solved the "white pollution" problem of PE protective film from the source, reduced the occupation of landfills, soil damage, and marine microplastic pollution, protected the balance of the ecosystem, and helped achieve the global "dual carbon" goal, promoting the transformation of the PE protective film industry from a "linear economy" to a "circular economy", with significant ecological and social benefits.
The fourth is economic value, which drives the coordinated development of the industrial chain. The production and application of PE3000 masterbatch can drive the development of upstream and downstream industries such as PE raw materials, catalysts, and microbial activation factors, forming a full life cycle green industry chain of "raw materials masterbatch products recycling degradation", promoting the transformation of the packaging industry towards low carbonization, recycling, and environmental protection, enhancing the international competitiveness of China's packaging industry, providing more job opportunities for society, and promoting high-quality economic development.
(3) Market prospect: Trillion level green market with huge potential
With the continuous tightening of global plastic restriction policies and the increasing environmental awareness of consumers, the biodegradable PE protective film market has entered an explosive period with huge market potential. With progressiveness technology, industrial adaptability and cost economy, Lvzhihui PE3000 anaerobic biodegradation masterbatch has a significant competitive advantage in the global degradable PE masterbatch market and can quickly seize the market share. At the same time, Green Hub will continue to promote technological iteration, optimize product performance, expand application scenarios, collaborate with upstream and downstream enterprises in the industry chain, build a full lifecycle green industry chain, and promote the high-quality development of the global PE protective film industry.
V. Conclusion
The continuous promotion of the global plastic restriction policy has pushed the plastic packaging industry into a new era of "environmental compliance, technological innovation, and circular development". PE protective film, as the core material of industrial protection, its green transformation is a key link in achieving the global plastic restriction goal. The non degradability of traditional PE protective films and the shortcomings of existing degradation technologies have led to severe compliance challenges and environmental pressures for the industry. The emergence of Green Hub PE3000 anaerobic biodegradable masterbatch provides a systematic and practical solution to this problem.
PE3000 anaerobic biodegradation masterbatch utilizes a dual technological innovation of "microbial activation+molecular chain catalysis" to achieve complete biodegradation of PE protective film in three major scenarios: landfill, soil, and seawater. The degradation cycle can accurately match the full lifecycle requirements of 1-3 years; At the same time, the product is perfectly compatible with the existing PE processing system, with controllable cost increase and stable protective performance. It has solved the three core pain points of "difficult compliance, expensive transformation, and poor performance" in the PE protective film industry, providing a technological path that combines academic innovation, industrial feasibility, and environmental friendliness for the green transformation of the global PE protective film industry.
As one of the advanced enterprises in China's plastic degradation technology, Luoyang Lvzhihui Plastic Degradation Technology Co., Ltd. will continue to deepen its cultivation in the field of anaerobic biodegradation technology, promote the technological iteration and application expansion of PE3000 masterbatch, optimize production processes, reduce product costs, and strengthen cooperation with domestic and foreign scientific research institutions and industry chain enterprises to conduct in-depth research on degradation mechanisms, environmental impacts, and other aspects, improve the green industry chain throughout the entire life cycle, and contribute Chinese wisdom and strength to global plastic pollution control, circular economy development, and ecological civilization construction.
The promotion and application of Green Hub PE3000 anaerobic biodegradation masterbatch will not only promote the green transformation of the PE protective film industry, but also provide a reference and promotable Chinese solution for the environmental governance of disposable and industrial plastic packaging worldwide, opening a new era of green development of PE packaging and helping the world achieve the ecological goal of "no plastic pollution".
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