Russia Hermetic Motor Market Overview, 2030

Plastic recycling in Canada has evolved gradually over the past four decades, shaped by municipal initiatives, policy frameworks, and more recently, national circular economy goals. Early recycling efforts began in the late 1980s and early 1990s, when municipalities introduced curbside collection programs for paper, metals, and select plastics, primarily PET and HDPE bottles. By the 2000s, most provinces had established province-wide blue box programs or equivalent collection systems, making plastic recycling accessible to a majority of households. However, recycling rates remained modest, averaging below 15%, with wide regional variation due to differences in infrastructure and funding. A pivotal moment occurred in 2018 when China’s National Sword policy restricted imports of plastic waste, forcing Canada, like the U.S., to re-evaluate its reliance on export markets and invest in domestic processing capacity. Since then, provincial extended producer responsibility (EPR) schemes have expanded, with British Columbia being an early leader, transferring recycling costs and management responsibilities from municipalities to producers. More recently, Canada announced a federal ban on certain single-use plastics, including checkout bags, cutlery, and straws, effective from 2022, alongside national targets to achieve at least 50% recycled content in plastic packaging by 2030. At the industrial level, major resin producers and recyclers are scaling chemical recycling pilots, with companies like NOVA Chemicals and Pyrowave investing in depolymerization and advanced recycling technologies to handle mixed and contaminated plastics. Collectively, Canada’s plastic recycling market is transitioning from fragmented provincial programs toward a more unified, EPR-driven system that emphasizes both mechanical and advanced recycling to meet environmental and economic objectives.

According to the research report, ""Canada Plastic Recycling Market Overview, 2030,"" published by Bonafide Research, the Canada Plastic Recycling market is anticipated to add to more than USD 620 Million by 2025–30. Canada’s regulatory and policy environment for plastic recycling is evolving rapidly as the country aligns waste management with circular economy objectives. At the federal level, the Government of Canada has committed to achieving zero plastic waste by 2030, a target supported by the Canadian Environmental Protection Act (CEPA), under which plastic manufactured items were added to the list of toxic substances in 2021. This designation enabled the federal ban on single-use plastics such as checkout bags, cutlery, straws, and foodservice ware, introduced in phases beginning in 2022. The federal government has also proposed minimum recycled-content standards, aiming for at least 50% recycled content in plastic packaging by 2030, supported by national reporting requirements. At the provincial level, Extended Producer Responsibility (EPR) schemes are central to Canada’s recycling framework. British Columbia was the first province to adopt full producer responsibility for packaging and printed paper through Recycle BC, achieving higher recovery rates than the national average. Other provinces including Ontario, Quebec, and Alberta are transitioning municipal “blue box” programs into EPR systems, shifting collection and recycling costs onto producers. Deposit Return Systems (DRS) for beverage containers are also well established in provinces like Alberta and Nova Scotia, achieving PET bottle recovery rates above 70%. Food-contact safety regulations for recycled plastics fall under the Canadian Food Inspection Agency (CFIA) and Health Canada, which require pre-market approval of recycling processes for materials intended for food packaging. Collectively, Canada’s policy framework is moving toward harmonized national standards while leveraging provincial leadership in EPR and DRS to scale recycling infrastructure and increase recycled-content adoption.

Canada’s plastic recycling performance differs markedly by resin, shaped by collection systems, provincial policies, and end-market demand. Polyethylene terephthalate (PET) leads, driven by strong bottle collection through deposit return systems and blue box programs; PET recovery often exceeds 70% in provinces with DRS, supplying food-grade rPET for bottles, thermoformed trays and fibers while industry investments have expanded domestic food-contact capacity. High-density polyethylene (HDPE) is the next most recovered resin, recovered from milk jugs, detergent bottles and rigid containers; rHDPE finds uses in bottles, piping and crates and benefits from stable industrial markets, although inconsistent municipal capture and contamination limit uniform food-grade output. Polypropylene (PP) recycling has grown but remains constrained by limited curbside acceptance and sorting challenges; post-industrial PP provides most high-quality feedstock for automotive parts, closures and industrial applications, while emerging mechanical and chemical routes aim to scale post-consumer PP into packaging. Low-density polyethylene (LDPE) film and flexible packaging face persistent obstacles: light weight, contamination and mixed structures reduce mechanical recycling yields, so recovery mainly relies on retail drop-offs and industrial film take-backs, with chemical recycling pilots seeking to convert films into feedstock. Polyvinyl chloride (PVC) recycling is niche because of additives and food-safety concerns, limited largely to construction offcuts and industrial streams. Polystyrene (PS) recovery is low for foams and foodservice items; selective densification programs and depolymerization pilots target styrene monomer recovery. “Other” engineering plastics—ABS, polycarbonate, nylon—are principally recovered from industrial and e-waste streams for electronics, automotive and specialty applications where quality controls permit higher-value reuse and growth.

In Canada, the plastic recycling market by source is heavily shaped by the contrast between post-consumer and post-industrial plastic waste, each carrying distinct challenges and opportunities. Post-consumer plastic waste accounts for the bulk of the country’s collection streams, dominated by packaging, single-use items, and household products captured through curbside “Blue Box” programs, deposit return systems (DRS), and retail take-back schemes. Deposit-based recovery systems in provinces such as British Columbia and Alberta deliver high capture rates for PET and HDPE beverage containers, often above 70%, providing a relatively clean feedstock. However, contamination from mixed plastics, food residue, and multilayer packaging continues to lower yields and drive down material quality, especially for LDPE films and PP packaging. To address these challenges, several provinces are transitioning to full Extended Producer Responsibility (EPR) models, shifting collection and processing costs to producers, and encouraging investments in advanced sorting and chemical recycling technologies. On the other hand, post-industrial plastic waste represents a smaller but higher-quality stream, generated primarily from manufacturing offcuts, automotive parts, construction materials, and agricultural films. This category typically offers cleaner, more homogenous inputs, which are easier to recycle mechanically into high-value applications such as automotive components, industrial packaging, and construction products. Large-scale industrial clusters in Ontario, Quebec, and Alberta have established closed-loop systems where production scraps are directly reintegrated into new products, helping maintain material value. While post-consumer volumes are far larger and central to meeting Canada’s recycling targets, post-industrial waste provides a vital foundation for high-quality recyclates, ensuring consistent supply for industries requiring stringent performance standards.

In Canada, plastic recycling is undergoing a transition shaped by the interplay between mechanical recycling and the emerging chemical recycling market. Mechanical recycling remains the dominant process, accounting for the majority of recycled volumes, particularly for PET and HDPE, which benefit from established collection through deposit return systems and curbside blue box programs. Mechanical methods are cost-effective and well-suited to clear streams such as beverage containers, agricultural films, and rigid packaging; however, challenges persist around contamination, mixed resins, and the recyclability of multilayer packaging, which often results in downcycling into lower-value products such as non-food packaging, textiles, or construction materials. To enhance efficiency, Canadian recyclers are increasingly adopting advanced optical sorters, robotics, and AI-driven separation technologies, supported by producer responsibility organizations under Extended Producer Responsibility (EPR) mandates. In parallel, chemical recycling has gained momentum as a strategic response to Canada’s 2030 zero plastic waste goal, aiming to tackle hard-to-recycle plastics like LDPE films, polystyrene, and multilayer materials. Technologies such as pyrolysis, gasification, and depolymerization are being piloted and scaled, with Alberta emerging as a hub due to its petrochemical industry and supportive provincial policies that classify chemical recycling as manufacturing rather than waste disposal. Companies such as Nova Chemicals and partnerships with international players are investing in chemical recycling capacity to produce virgin-like polymers suitable for food-contact and high-performance applications. While mechanical recycling currently dominates, chemical recycling is expected to complement it by expanding feedstock acceptance and enabling circularity at scale, positioning Canada as a regional leader in advanced recycling innovation.

In Canada, the end-user demand for recycled plastics is led by the packaging industry, which accounts for the largest share of recycled plastic consumption due to high volumes of PET bottles, HDPE containers, and LDPE films collected through deposit return systems, blue box programs, and retail take-back schemes. Recycled PET (rPET) is extensively used in beverage bottles, trays, and fibers, while rHDPE is applied in bottles, detergent containers, and non-food packaging, supported by brand commitments from Coca-Cola, PepsiCo, and Nestlé to integrate recycled content. The electronics and electrical sector leverages recycled engineering plastics such as ABS, polycarbonate, and nylon recovered from post-industrial and e-waste streams for casings, housings, and components, with extended producer responsibility (EPR) programs for e-waste in provinces like Ontario ensuring steady material flows. The automotive industry represents another critical consumer, with recycled PP, HDPE, and engineering plastics used in bumpers, dashboards, interior trims, and underbody components; Canadian OEMs and suppliers increasingly incorporate recycled inputs to align with emission-reduction and circular economy targets. In building and construction, recycled PVC, HDPE, and PP are employed in piping, insulation, profiles, and composite panels, driven by steady infrastructure activity and regulatory support for recycled material use in public projects. The “others” segment includes textiles, agriculture, and consumer goods, where rPET is spun into polyester fibers for clothing and furnishings, recycled LDPE is applied in mulch films and irrigation pipes, and post-industrial ABS and nylon are reused in durable goods. Together, these industries not only absorb recycled plastics but also reinforce Canada’s transition toward a circular economy by creating reliable end markets for recyclates.


Considered in this report
• Historic Year: 2019
• Base year: 2024
• Estimated year: 2025
• Forecast year: 2030

Aspects covered in this report
• Plastic Recycling Market with its value and forecast along with its segments
• Various drivers and challenges
• On-going trends and developments
• Top profiled companies
• Strategic recommendation

By Product Types
• Polyethylene Terephthalate (PET)
• High-Density Polyethylene (HDPE)
• Polypropylene (PP)
• Low-Density Polyethylene (LDPE)
• Polyvinyl Chloride (PVC)
• Polystyrene (PS)
• Others (ABS, Polycarbonate, Nylon, ETC.)

By Source
• Post-Consumer Plastic Waste
• Post-Industrial Plastic Waste

By Recycling Process
• Mechanical Recycling market
• Chemical recycling
• By End User Industries
• Packaging
• Electronics & Electrical
• Automotive
• Building & Construction
• Others 

Considered in this report
• Historic Year: 2019
• Base year: 2024
• Estimated year: 2025
• Forecast year: 2030

Aspects covered in this report
• Hermetic Motor Market with its value and forecast along with its segments
• Various drivers and challenges
• On-going trends and developments
• Top profiled companies
• Strategic recommendation

By Power Output
• Fractional Horsepower (Up to 1HP)
• Integral Horsepower (Above 1HP)

By Voltage
• Upto 1kV
• 1kV-6.6kV
• Above 6.6kV

By Application
• Industrial Machinery
• Motor Vehicles
• HVAC Equipment
• Electrical Appliances
• Others Show more