|
Forecast Period
|
2026-2030
|
|
Market Size (2024)
|
USD 28.66 Billion
|
|
Market Size (2030)
|
USD 50.23 Billion
|
|
CAGR (2025-2030)
|
9.64%
|
|
Fastest Growing Segment
|
Dynamic Compressors
|
|
Largest Market
|
North America
|
Market Overview
Global
Biogas
Compression Market was
valued at USD 28.66 Billion in 2024 and is expected to reach USD 50.23 Billion by
2030 with a CAGR of 9.64% during the forecast period.
The global
biogas compression market is experiencing robust growth, driven by the rising
demand for renewable energy sources, growing environmental awareness, and
government incentives promoting biogas utilization. Biogas, primarily composed
of methane and carbon dioxide, is generated from organic waste through
anaerobic digestion and is increasingly being used as a substitute for fossil
fuels in power generation, heating, and transportation. However, to be
effectively transported, stored, or upgraded to biomethane, biogas must be
compressed to higher pressures, creating a critical demand for advanced biogas
compression technologies. The market is benefiting from the rapid expansion of
biogas plants, especially in regions such as Europe, North America, and parts
of Asia-Pacific, where strong regulatory support and feed-in tariffs are
encouraging biogas production.
Technological
advancements in compressor design, such as oil-free reciprocating and screw
compressors, are enhancing reliability, energy efficiency, and maintenance
cycles, thereby improving their adoption across industrial and municipal
sectors. Positive displacement compressors, particularly rotary screw and
reciprocating types, dominate the market due to their proven performance in
handling varying gas volumes and pressures in biogas applications.
Additionally, dynamic compressors are gaining popularity in high-capacity
installations, especially for pipeline injection or bio-CNG bottling. The
market also sees a growing preference for electric motor-driven compressors due
to their energy efficiency and lower emissions, aligning with global
decarbonization goals.
End-use
industries such as agriculture, food & beverage, and municipal waste
management are leading adopters, with agricultural biogas projects gaining
momentum due to their dual benefits of waste management and energy generation.
Moreover, the vehicle fuel segment, particularly for bio-CNG applications, is
anticipated to witness the fastest growth as countries aim to reduce transport
sector emissions. Europe currently holds the largest market share, thanks to
its established biogas infrastructure and stringent climate targets, while
Asia-Pacific is emerging as the fastest-growing region, driven by rising energy
demand, supportive policies in countries like India and China, and growing
awareness of sustainable waste-to-energy solutions.
Despite the
optimistic outlook, the market faces challenges such as high initial
investment, technical complexities in gas purification and compression, and the
need for skilled labor. However, ongoing innovations, declining equipment
costs, and growing private and public investments are expected to mitigate
these hurdles. As nations seek to decarbonize their energy systems, the biogas
compression market is poised for sustained expansion, playing a pivotal role in
the transition toward a circular and low-carbon energy economy.
Key Market Drivers
Rising Demand for Renewable
Energy & Decarbonization
The global transition to
cleaner energy sources is significantly boosting demand for biogas compression
technologies. Countries are increasingly incorporating biogas into their
renewable energy mix to meet carbon reduction targets. Approximately 70% of nations
globally have committed to net-zero emissions, prompting large-scale adoption
of biogas as a clean substitute for fossil fuels. Over 1 billion tons of
organic waste are generated annually, forming a robust feedstock base for
biogas production. In Europe alone, more than 20,000 biogas plants are
operational, many of which require advanced compression systems for biomethane
injection into gas grids. About 25–30% of agricultural biowaste is now being
converted into biogas, reducing methane emissions and supporting rural energy
independence. Countries are also observing up to 10–13% reduction in
greenhouse gases through enhanced biogas utilization. This rising demand is
creating a sustained need for compression units capable of upgrading raw biogas
to pipeline or vehicle-grade biomethane.
Robust Government
Incentives and Policy Support
Government incentives are a
major catalyst driving the adoption of biogas compression systems. Across
multiple regions, regulatory frameworks have introduced capital subsidies
covering up to 40–60% of the total project cost for biogas infrastructure. Tax
exemptions on compressed biogas sales in many countries help reduce the payback
period by an estimated 2 to 3 years. More than 1,000 new biogas upgrading
projects are in the pipeline globally, driven by national targets and mandatory
renewable fuel obligations. In Asia, policies support the installation of
over 5,000 new compressed biogas plants under clean energy programs. Feed-in
tariffs for grid-injected biomethane have increased by up to 20% in select
markets, making it more economically viable. Additionally, emission trading
systems are beginning to include biogas-derived carbon credits, further
enhancing project returns and encouraging investment in high-efficiency
compressor technologies.
Technological Advancements
in Compression Systems
Advancements in biogas
compression technology have significantly improved efficiency, durability, and
adaptability. Newer oil-free reciprocating and screw compressors now operate
with energy savings of up to 15–20% compared to legacy systems. Modern biogas
compressors come equipped with predictive maintenance software, reducing
unplanned downtime by as much as 30%. Compact, modular designs allow
installation in small-scale farms as well as large industrial sites with
capacities ranging from 50 kW to 500 kW and beyond. Systems equipped with
variable frequency drives enable better handling of fluctuating biogas flow
rates, improving operational flexibility. Material improvements such as
corrosion-resistant coatings have increased average equipment lifespans from 7
to 12 years. As compressor efficiency and automation improve, operating costs
decrease, making it easier for smaller developers and municipalities to enter
the market.
Growth in Organic Waste and
Circular Economy Goals
The rising volume of
organic waste from agriculture, food processing, and municipal systems is
directly contributing to the expansion of biogas production—and with it,
compression systems. Annually, over 1.3 billion tons of food waste and 700
million tons of agricultural waste are generated globally. This offers vast
potential for decentralized and centralized biogas systems, most of which
require compression for bottling, storage, or pipeline distribution. In
urban areas, biogas derived from wastewater treatment plants accounts for
nearly 30% of renewable gas inputs. Agricultural operations now integrate
biogas units in more than 80 countries, converting manure and crop waste into
both energy and fertilizer. Around 10% of total rural households in developing
economies use small-scale biogas digesters, many supported by basic compression
modules. The global push for circular economy models—recycling waste into
energy—is expected to increase biogas plant installations by 50% in the next
five years, further strengthening demand for reliable compression technologies.
Expanding End-Use
Applications in Transportation and Grid Injection
Diversification of biogas
end-use applications is driving compressor adoption. Compressed biogas, also
known as bio-CNG, is now being used to fuel over 20,000 commercial vehicles
globally, with adoption growing annually by 10–15%. Biomethane is also
increasingly injected into national gas grids, which requires precise
high-pressure compression at levels of 150–300 bar. In countries with
advanced natural gas networks, biogas now accounts for up to 10% of grid input
during peak periods. Large utilities and logistics firms are investing in
refueling stations for bio-CNG trucks and buses, which require on-site
compression equipment capable of handling volumes above 100 Nm³/h. In addition,
industrial users are adopting biogas as a substitute for LPG and diesel in
thermal processes, increasing the need for medium- and high-pressure
compressors. Seasonal energy storage is also emerging, where compressed biogas
is stored during high production months and utilized later, requiring robust
compression and bottling solutions.
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Key Market Challenges
High
Capital Investment and Operational Costs
One of the most significant
challenges in the biogas compression market is the high initial capital
investment required for setting up compression systems. Compressors—especially
high-pressure models needed for vehicle-grade bio-CNG or pipeline injection—can
cost tens of thousands of dollars per unit. These costs increase further when
including installation, ancillary equipment like gas drying and filtration
units, and advanced control systems. For small-scale biogas producers such as
farms or rural cooperatives, this upfront cost often becomes prohibitive.
Operational costs also present a hurdle. Compressors typically consume a
substantial amount of electricity, sometimes accounting for over 25% of a
biogas plant’s energy usage. Maintenance costs are also high, especially for
oil-free or high-speed systems where parts wear out quickly. The need for
corrosion-resistant materials and advanced monitoring systems further inflates
ongoing expenses. Furthermore, due to pressure and safety requirements, certified
technicians are needed for installation and servicing, which adds to labor
costs. In emerging markets, access to skilled service providers is limited,
leading to increased downtime or expensive third-party servicing. This cost
burden can extend the payback period significantly, discouraging investment.
While government subsidies exist in some regions, they are often inconsistent
or unavailable for compression-specific components. Without sufficient
financial support or scaling mechanisms, many potential adopters delay or
cancel implementation, limiting market expansion.
Inconsistent
Quality and Composition of Biogas Feedstock
The variable nature of raw
biogas presents a considerable challenge for compression systems. Biogas
composition can fluctuate significantly depending on the feedstock
source—whether it's animal manure, food waste, or sewage sludge. Methane
content can range from 45% to 75%, while the concentration of hydrogen sulfide
(H₂S), moisture, and carbon dioxide varies widely. Such inconsistencies can
impact compressor performance, reduce system efficiency, and lead to premature
equipment wear. High levels of H₂S are particularly
corrosive and, if not properly removed in pre-treatment stages, can damage
compressor components. Similarly, moisture in biogas causes internal
condensation and corrosion, increasing maintenance frequency. Most compressor
systems are designed to operate within a narrow set of gas quality parameters;
deviations from this range reduce operational life and increase energy
consumption. In decentralized and rural settings, where pre-treatment systems
like desulfurizers or chillers are either rudimentary or absent, compressors
face higher failure rates. This leads to increased operating costs and reduced
reliability. Additionally, fluctuating gas flow rates due to inconsistent waste
feed input or seasonal variations create inefficiencies in load management.
Unless compressors are fitted with advanced controls such as variable frequency
drives and sensors, they often run below optimal capacity. Inconsistent biogas
quality also complicates standardization and increases customization costs,
especially for manufacturers targeting global or multi-application markets.
Technical
Complexity and Lack of Skilled Workforce
Biogas compression systems
are technically complex, requiring a combination of mechanical, electrical, and
chemical engineering expertise to operate efficiently and safely. Unlike
traditional gas compression systems, biogas compressors must deal with contaminants,
pressure variations, and safety risks associated with handling flammable and
corrosive gases. This complexity makes installation, monitoring, and
maintenance more challenging, especially in regions where the technical skill
base is still developing. Many developing and emerging economies face a severe
shortage of trained professionals who can design, install, and service advanced
biogas compression units. As a result, even when systems are installed,
operators may lack the knowledge to run them optimally, leading to
inefficiencies or even hazardous situations. This skills gap extends to
manufacturers and system integrators, who may need to customize training
modules for each end-user, increasing the overall cost of deployment. The
unavailability of local spare parts and limited after-sales support further
compounds the issue. In the absence of robust service networks, operators face
delays in repairs, resulting in extended downtimes and reduced profitability.
The lack of formalized certification or regulatory training programs for
technicians in biogas compressor maintenance also restricts professional
development and limits the market’s scalability. As more complex digital
components like IoT-based sensors and automated monitoring systems are integrated
into compressors, the need for multidisciplinary expertise grows, further
widening the gap in technical readiness.
Regulatory
Uncertainty and Policy Gaps
While government incentives
and policies have supported the growth of biogas production in many regions,
regulatory frameworks specifically addressing compression systems remain
inconsistent or unclear. In several countries, biogas policies focus on production
and feed-in tariffs but overlook infrastructure needs such as compression,
bottling, or vehicle-grade fuel standards. This regulatory oversight creates
uncertainty for investors and project developers who require clear guidelines
on safety, emissions, and quality standards. Inconsistencies between national,
state, and municipal regulations further complicate project planning. For
instance, compression systems approved for pipeline injection in one
jurisdiction may not be valid in another due to different pressure or purity
requirements. This lack of harmonization leads to delays in permitting,
increases compliance costs, and creates barriers to scaling operations across
regions. Moreover, the absence of clear policies for grid access, carbon credit
eligibility, or tax exemptions for compression equipment discourages
investment. In some cases, biogas upgrading and compression are taxed similarly
to fossil fuel operations, nullifying the environmental benefits. Without a
strong policy ecosystem to support compression-specific infrastructure, many
projects remain stuck at the feasibility stage or operate below potential.
Clear, harmonized standards for biogas compression across regions, combined
with streamlined approval processes, are essential to mitigate this challenge
and promote a consistent market environment.
Limited
Infrastructure and Supply Chain Bottlenecks
Another significant
challenge in the biogas compression market is the lack of supportive
infrastructure and supply chain maturity, particularly in developing regions.
Many rural or semi-urban areas with high biogas potential lack access to
natural gas pipelines, high-voltage electricity lines, or roads capable of
transporting large compressor units. This limits the feasibility of deploying
compression systems in off-grid or hard-to-reach areas. Additionally, global
supply chains for compressor components—such as pressure vessels, specialized
valves, and sensors—remain fragile, often affected by geopolitical disruptions
or raw material shortages. Lead times for customized compressors can extend to
several months, delaying project timelines. The absence of regional
manufacturing hubs for biogas-specific compressors means most units are
imported, increasing logistics costs and exposing buyers to currency
fluctuations. Spare parts availability is also limited, forcing operators to
maintain excess inventory or face extended downtimes. Aftermarket support is
often insufficient, with only a handful of specialized service providers in
most countries. The situation is further strained when dealing with proprietary
systems, which require exclusive service tools or OEM-certified personnel. All
of these factors collectively increase the total cost of ownership and reduce
the market’s ability to respond flexibly to demand surges. Strengthening local
supply chains, setting up regional service hubs, and fostering public-private
infrastructure partnerships will be crucial to overcoming these limitations.
Key Market Trends
Rising Adoption of Modular
and Containerized Compression Units
Modular and containerized
compressor systems are gaining strong traction in the global biogas compression
market due to their portability, scalability, and ease of installation. These
plug-and-play solutions are pre-engineered, pre-assembled, and housed in
compact enclosures that can be transported to remote or decentralized biogas
production sites. With the rise in small- and medium-scale biogas plants,
especially in rural and off-grid areas, modular compressors offer a flexible
solution for upgrading and bottling without the need for large infrastructure.
These systems come pre-integrated with gas purification components such as
moisture traps, filters, and scrubbers, reducing the need for multiple vendors
or complex site setups. Containerized units also support rapid commissioning,
often within a few days, compared to several weeks for traditional
installations. This makes them highly suitable for temporary or pilot projects,
agricultural farms, and emergency backup applications. The scalability of modular
units allows operators to add capacity incrementally as feedstock or energy
demand grows, optimizing capital expenditure. Additionally, standardized
designs simplify maintenance and reduce the learning curve for operators. With
their compact footprint and all-weather enclosures, containerized compressors
are also ideal for harsh climates or urban spaces where zoning is a constraint.
As decentralized energy production gains momentum globally, especially in
regions like Southeast Asia, Africa, and parts of Europe, this trend is
expected to drive significant market expansion.
Expansion of Bio-CNG and
Transportation Fuel Applications
A significant trend shaping
the biogas compression market is the growing use of compressed biogas (bio-CNG)
as a renewable transportation fuel. Governments and industries are increasingly
promoting bio-CNG as a low-emission alternative to diesel and petrol,
particularly for heavy-duty vehicles, buses, and municipal fleets. Biogas must
be compressed to 200–250 bar to be used as vehicle fuel, driving the need for
high-performance compressor systems. With thousands of bio-CNG vehicles already
on the road in Europe and South Asia, demand for refueling
infrastructure—powered by onsite compressors—is rapidly growing. For instance,
several countries have launched programs to convert public transportation
fleets to bio-CNG, resulting in a surge of filling stations equipped with
advanced compression units. Private logistics and delivery companies are also
investing in captive biogas plants paired with compressors to reduce fuel costs
and meet ESG goals. Moreover, bio-CNG production is eligible for carbon credits
and clean fuel subsidies in many regions, making it financially attractive. As
vehicle-grade biogas gains policy recognition and market maturity, compressor
manufacturers are designing systems tailored for mobility applications—focusing
on rapid refill time, safety features, and energy efficiency. This trend is not
only diversifying the use of biogas but also establishing a resilient
downstream ecosystem for compressor technologies.
Increased Focus on
Upgrading Biogas to Biomethane for Grid Injection
Another major trend is the
push toward upgrading raw biogas to biomethane and injecting it into existing
natural gas grids. This process requires reliable and efficient compression
systems that can maintain consistent pressure and purity levels. With natural
gas infrastructure already widely established in regions such as Europe and
North America, biomethane injection allows utilities to decarbonize their
energy supply without building entirely new distribution systems. Countries are
setting ambitious targets for biomethane integration, with some aiming to
replace up to 20% of fossil gas with renewable gas by 2030. To meet grid
injection standards, biogas must be cleaned and compressed to pressures
typically ranging from 15 to 30 bar, making compressors an essential component
of the upgrading process. This trend has led to innovations in compressor
designs that are more compatible with membrane separation, pressure swing
adsorption (PSA), and water scrubbing systems. Utilities and third-party
developers are increasingly collaborating on integrated biogas-to-grid
projects, often backed by feed-in tariffs or renewable gas certificates. In
response, compressor manufacturers are offering turnkey compression skids that
simplify integration into biogas upgrading plants. As the emphasis on
grid-ready biomethane grows globally, the role of compressors in ensuring
efficient, safe, and stable injection is becoming increasingly critical.
Growth in Decentralized and
Off-Grid Biogas Systems
Decentralized energy
production using biogas is emerging as a prominent trend, particularly in
developing countries and remote areas. These off-grid systems often serve
agricultural communities, industrial clusters, or small municipalities that
lack access to centralized energy infrastructure. Compressors are essential in
such setups for storing or transporting biogas as a fuel for cooking, heating,
or electricity generation. Unlike large utility-scale biogas facilities,
decentralized systems operate at lower flow rates and pressures but still
require compact and reliable compressors to function efficiently. Governments
and non-profits are supporting these installations with subsidies and training
programs, particularly in Asia and Africa, where rural electrification and
waste management are top priorities. The rise of microgrids powered by biogas
is further amplifying this trend, as communities seek resilient, localized
energy solutions that are not dependent on national grids. Manufacturers are
responding by developing low-capacity, energy-efficient compressors tailored
for decentralized usage. These include solar-powered units and manually
operated options where electric supply is unreliable. Additionally,
containerized and mobile compressors are enabling flexible deployment in
humanitarian, agricultural, and disaster-recovery applications. As
sustainability goals align with rural development strategies, the biogas
compression market is expected to see sustained growth in decentralized,
off-grid segments worldwide.
Segmental Insights
Technology Insights
Positive
Displacement Compressors segment dominated in the Global Biogas Compression market
in 2024 due to
its reliability, energy efficiency, and suitability for handling variable gas
flows typical of biogas production. These compressors, which include reciprocating
and rotary screw types, are designed to deliver consistent pressure output even
under fluctuating inlet conditions, making them ideal for biogas plants where
gas composition and flow rates vary based on feedstock and digestion cycles.
One of the
primary reasons for their dominance is their superior ability to manage low and
medium gas volumes at relatively low suction pressures, which is common in
biogas generation. Positive displacement compressors can efficiently compress
biogas with methane content ranging from 50% to 70% while handling impurities
such as moisture, hydrogen sulfide, and CO₂—challenges that
can degrade other types of compressors more rapidly.
In addition, oil-free
reciprocating compressors are increasingly favored in applications like
biomethane upgrading and bio-CNG fueling, where gas purity is critical. These
units minimize contamination risk, meet stringent emission standards, and are
easier to maintain in decentralized setups. Rotary screw compressors, on the
other hand, are valued for their continuous operation and high efficiency,
particularly in mid- to large-scale facilities.
Moreover, technological
advancements—including integration with variable frequency drives (VFDs), smart
control panels, and predictive maintenance systems—have significantly enhanced
the performance and lifespan of positive displacement systems. Their modular
and compact design makes them easier to install in both fixed and mobile
configurations, supporting trends like containerized biogas plants.
As governments
push for renewable energy adoption and decentralized waste-to-energy systems,
the demand for compressors that combine durability, adaptability, and energy
efficiency has risen—placing positive displacement compressors firmly at the
forefront of the global biogas compression landscape in 2024.
Power Rating Insights
50–200 kW segment dominated the Global Biogas Compression market in
2024 due to its
suitability for medium-scale biogas plants, which represent the majority of
installations globally. These compressors offer the right balance between
performance and energy efficiency for applications like agricultural digesters,
municipal wastewater plants, and small industrial setups. They are
cost-effective, easy to maintain, and compatible with modular and containerized
biogas systems. As decentralized energy production gained momentum—particularly
in Europe and Asia—demand surged for compressors in this power range, which
effectively handle fluctuating gas volumes while ensuring reliable compression
for grid injection or bio-CNG use.
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Regional Insights
Largest Region
North America dominated the Global Biogas
Compression market in 2024 owing to its well-established biogas infrastructure,
supportive regulatory environment, and strong investments in renewable energy
and sustainable waste management. The region—led by the United States and
Canada—has significantly expanded its network of biogas plants, particularly in
agriculture, landfills, and municipal wastewater treatment facilities. These
facilities require reliable and efficient gas compression systems to upgrade
raw biogas into biomethane or compress it for use as bio-CNG, driving sustained
demand for advanced compressors.
One of the major
factors behind North America’s leadership is the policy support from federal
and state governments. In the U.S., the Renewable Fuel Standard (RFS) and Low
Carbon Fuel Standard (LCFS) programs have incentivized the production and use
of renewable natural gas (RNG), a purified form of biogas. These incentives
make it financially viable for biogas producers to invest in high-performance
compression systems. Moreover, over 2,000 biogas sites are currently
operational across the U.S., with more under development, especially in
livestock farms and food waste recovery centers.
North America
also benefits from a mature natural gas pipeline infrastructure, allowing
biomethane injection and distribution on a large scale. This infrastructure
supports the widespread adoption of biogas upgrading and compression
technologies, enabling RNG to be used in both power generation and
transportation fuel applications. Additionally, the presence of leading
compressor manufacturers and technology providers in the region ensures access
to advanced, customizable, and efficient systems tailored to various biogas
sources.
Growing interest
in carbon-neutral transportation has also fueled the installation of bio-CNG
refueling stations, further pushing the demand for high-pressure biogas
compressors. Combined with rising corporate investments in sustainability and
growing public-private partnerships, these factors make North America the most
dominant and technologically advanced market for biogas compression in 2024.
Emerging Region
Europe was the emerging region in the Global Biogas
Compression market in the coming period due to its ambitious climate targets,
strong policy support, and expanding biomethane infrastructure. The EU’s
REPowerEU plan aims to produce 35 billion cubic meters of biomethane by 2030,
significantly increasing demand for compression systems. Countries like
Germany, France, and the Netherlands are rapidly scaling up biogas plants and
grid injection projects. Additionally, widespread adoption of bio-CNG vehicles,
government subsidies, and advancements in upgrading technologies are
accelerating compressor deployment. Europe’s focus on energy independence and
circular economy principles further strengthens its position as a
high-potential biogas compression market.
Recent Developments
- In April 2025, BPCL and GPS
Renewables Private Limited formalized a joint venture agreement to establish
compressed biogas (CBG) plants across India. This partnership, first announced
in September 2024, aligns with BPCL’s Net Zero goals and India’s broader energy
transition agenda. The agreement was signed by senior leadership from both
organizations, underscoring a shared commitment to scaling sustainable energy
solutions in line with national decarbonization targets and the development of
circular, waste-to-energy infrastructure.
- In April 2025, Telangana secured INR1,500 crore in CBG investments through a strategic
alliance between South Africa’s Biovest Holdings and Hyderabad-based Spantech
Engineers and EcoMax Energy. The partnership will establish 20 CBG plants
statewide. A bilateral technology transfer deal enables Spantech to locally
manufacture Biovest’s Herba anaerobic digestion technology, noted for
delivering triple the biomethane yield. Spantech will also supply its
proprietary BioGenie purification systems, positioning Telangana as a key hub
for biogas innovation and sustainable infrastructure.
- In July 2024, Burckhardt
Compression was selected as the preferred supplier for 45 biogas projects
across India during the previous fiscal year. The company secured orders for 82
high-pressure compressors, reinforcing its strategic growth in clean energy
markets. As the global biogas sector expands—projected to grow from 5% to 20%
by 2040—Burckhardt’s technological leadership in reciprocating compressors is
enabling key decarbonization efforts, methane emission reduction, and
acceleration of circular economy goals across emerging economies like India.
- In April 2025, BPCL shares
were trading at INR304.20 on the NSE, up INR3.75 or 1.25% from the previous
close of INR300.45. The stock opened at INR302.95 and reached an intraday high
of INR305.50, with a low of INR300.80. This upward movement reflects continued
investor confidence, supported by strategic sustainability initiatives,
including recent biogas infrastructure partnerships, aligning with BPCL’s
long-term growth and decarbonization roadmap.
Key
Market Players
- Atlas Copco AB
- Aerzen
- Gardner Denver
- Bauer Compressors,
Inc.
- HAUG Sauer Kompressoren
AG
- Enea Mattei
SpA
- Mehrer Compression
GmbH
- Tecno Project Industriale
Srl
- Avelair
- Fornovo Gas S.p.A.
|
By Technology
|
By Power Rating
|
By End-User
|
By Region
|
- Positive
Displacement Compressors
- Dynamic
Compressors
|
- Below 50 kW
- 50–200 kW
- Above 200 kW
|
- Agriculture
- Municipal
Waste Management
- Food &
Beverage Industry
- Chemical
& Petrochemical
- Power
Generation Utilities
|
- North
America
- Europe
- South
America
- Middle East
& Africa
- Asia Pacific
|
Report Scope:
In this report, the Global Biogas Compression
Market has been segmented into the following categories, in addition to the
industry trends which have also been detailed below:
- Biogas Compression Market, By Technology:
o Positive Displacement Compressors
o Dynamic Compressors
- Biogas Compression Market, By Power
Rating:
o Below 50 kW
o 50–200 kW
o Above 200 kW
- Biogas Compression Market, By End-User:
o Agriculture
o Municipal Waste Management
o Food & Beverage Industry
o Chemical & Petrochemical
o Power Generation Utilities
- Biogas Compression Market,
By Region:
o North America
§
United
States
§
Canada
§
Mexico
o Europe
§
Germany
§
France
§
United
Kingdom
§
Italy
§
Spain
o South America
§
Brazil
§
Argentina
§
Colombia
o Asia-Pacific
§
China
§
India
§
Japan
§
South
Korea
§
Australia
o Middle East & Africa
§
Saudi
Arabia
§
UAE
§
South
Africa
Competitive Landscape
Company Profiles: Detailed analysis of the major companies
present in the Global Biogas Compression Market.
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the given market data, TechSci Research offers customizations according to a
company's specific needs. The following customization options are available for
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