Chemicals & Material // Lubricants
The global heat transfer fluids market is
foreseen to grow by 8.9%, from USD 4.12 Billion in 2022 to USD 8.15 billion in
2030. Rapid industrialization and supportive renewable energy policies in Asia
Pacific, growing number of concentrating solar power projects, increased use of
Heat transfer fluids (HTFs) to reduce operating costs and save energy is to
drive the market for the upcoming forecast period. However, volatile raw
material prices remain one factor hindering the market growth over the
anticipated period.
Market Definition
What Is Heat Transfer Fluids?
Market Overview
Heat Transfer Fluids: Enhancing Efficiency and
Environmental Sustainability
Heat transfer fluids (HTFs) play a crucial role in
various industries, facilitating the efficient transfer of thermal energy. They
are essential in applications such as heating, cooling, and power generation.
This essay explores the significance of HTFs, their top impacting factors, and
government policies related to their usage. By addressing these aspects, we aim
to shed light on the importance of choosing appropriate HTFs and promoting
sustainable practices in heat transfer applications.
I. Importance of Heat Transfer Fluids
Heat transfer fluids serve as a medium for transferring
thermal energy from one location to another. They enhance the efficiency of
heat transfer processes, ensuring optimal performance in industrial
applications. HTFs are employed in a wide range of sectors, including oil and
gas, chemical processing, power generation, and solar thermal systems.
II. Top Impacting Factors
a) Thermal Stability: One of the crucial factors in
selecting HTFs is their ability to maintain thermal stability over a wide range
of temperatures. Thermal stability prevents degradation and enhances the
longevity of the fluid, reducing the frequency of replacements and minimizing
downtime in industrial operations.
b) Heat Transfer Efficiency: The heat transfer efficiency
of a fluid affects the overall performance of the system. Factors such as
thermal conductivity, viscosity, and specific heat capacity determine the rate
at which thermal energy can be transferred. HTFs with high heat transfer
coefficients contribute to improved energy efficiency.
c) Environmental Impact: Environmental considerations
have become increasingly important in heat transfer applications. The choice of
HTFs can significantly impact the ecosystem due to potential leaks, spills, or
improper disposal. Opting for environmentally friendly HTFs that have low
toxicity, high biodegradability, and low global warming potential is vital for
sustainable operations.
d) Compatibility with Materials: HTFs must be compatible
with the materials used in the heat transfer system to avoid corrosion,
scaling, or other detrimental effects. Compatibility with seals, gaskets, and
other system components is critical to ensure the longevity of the equipment.
III. Government Policies
a) Regulations on Fluid Selection: Governments around the
world are implementing regulations to encourage the use of environmentally
friendly HTFs. These policies aim to reduce the impact of HTF leaks or spills
on the environment and human health. For instance, certain countries have
phased out the use of chlorofluorocarbons (CFCs) as HTFs due to their ozone
depletion potential.
b) Safety Standards: Governments and regulatory bodies
have established safety standards and guidelines for HTF handling, storage, and
transportation. These regulations ensure the protection of workers, prevent
accidents, and minimize environmental risks.
c) Incentives for Sustainable Practices: Governments are
increasingly providing incentives and subsidies to promote the adoption of
sustainable heat transfer practices. These initiatives encourage industries to
invest in energy-efficient systems and choose HTFs with lower environmental
impacts, thereby reducing carbon emissions.
Dynamics of Heat Transfer Fluids Market
Drivers in Heat Transfer Fluids Market
Rapid industrialization and supportive renewable energy
policies in the Asia Pacific region have made it a highly appealing market for
heat transfer fluids (HTFs). The remarkable industrial growth experienced by
emerging economies, particularly China and India, has generated a significant
demand for HTFs. Key HTF manufacturers like Dow, Indian Oil Corporation,
Hindustan Petroleum Corporation Limited, and Dalian Rich Fortune Chemical
Company are employing marketing strategies such as product launches and
advancements to augment their market share in the Asia Pacific HTF market. In
the Asia Pacific region, the renewable energy sector, particularly in India, is
projected to be among the fastest-growing segments in the HTF market. The
increasing adoption of renewable energy for environmental preservation, social
development, and economic advantages further propels the growth of the HTF
market in Asia Pacific. Additionally, the Indian government is actively
encouraging the manufacturing sector to embrace green energy by implementing
supportive policies that promote renewable energy utilization.
Restraints in Heat Transfer Fluids Market
Fluctuating prices of raw materials
The prices of raw materials used in HTFs pose a
significant challenge for manufacturers. Key raw materials, such as phenol,
benzene, and glycol, are directly influenced by the fluctuating prices of crude
oil. Manufacturers must navigate through the volatility of raw material costs,
which can diminish their profit margins. The COVID-19 pandemic created
substantial disruptions in businesses and supply chains, severely impacting the
oil and gas industry and consequently hindering the growth of the heat transfer
fluid market. The reduced supply and demand for oil and gas, particularly in
North America and Europe, resulted in the suspension of onshore and offshore
production processes, adversely affecting the heat transfer fluids market.
Additionally, the installation of new solar power projects was put on hold, and
the operational activities of existing plants were disrupted, further impeding
the market's progress.
Opportunities in Heat Transfer Fluids Market.
Government initiatives focused on enhancing energy
efficiency and promoting renewable energy sources have created significant
prospects for growth. The National Action Plan for Energy Efficiency, a joint
effort between the US government and private entities, aims to establish a
sustainable and ambitious commitment to energy efficiency. This initiative
utilizes various methods, including the utilization of heat transfer fluids
(HTFs). Countries such as the US, Spain, China, and India have heavily invested
in solar power plants to meet their rising energy demands, reduce carbon
footprints, and decrease reliance on fossil fuels. Consequently, the demand for
HTFs in renewable energy applications is anticipated to rise. HTFs find
extensive application in diverse industries such as oil and gas, chemicals,
food and beverages, pharmaceuticals, automotive, and renewable energy. With
increasing industrial activities and a growing need for efficient heat transfer
processes, there are significant opportunities for heat transfer fluid
manufacturers. The transition towards renewable energy sources like solar
thermal, geothermal, and concentrated solar power necessitates effective heat
transfer fluids for optimal energy conversion and storage. This presents a
promising opportunity for heat transfer fluid suppliers to cater to the
escalating demand in the renewable energy sector. Furthermore, thermal energy
storage systems play a critical role in energy management and grid stability,
where heat transfer fluids are integral components. As the focus on energy
storage solutions intensifies, there is a favorable opportunity for heat
transfer fluid manufacturers to develop specialized fluids tailored for thermal
energy storage applications. Environmental regulations aimed at reducing
greenhouse gas emissions and improving energy efficiency are also driving the
demand for heat transfer fluids with minimal environmental impact. The
development of eco-friendly and sustainable heat transfer fluids enables
manufacturers to meet these regulatory requirements and satisfy the growing
demand for environmentally conscious solutions. Advancements in heat transfer
fluid technologies, including high-temperature fluids, nanofluids, and phase
change materials, offer opportunities for enhanced thermal efficiency and
performance. Manufacturers can leverage these advancements by introducing
innovative heat transfer fluids with superior properties.
Challenges in Heat Transfer Fluids Market
Fire and explosion hazards associated with
high-temperature heat transfer fluids (HTFs)
High-temperature applications in chemical plants, such as
plastic and metal processing, as well as specialty chemical production, require
the use of organic fluids due to the potential formation of explosive
atmospheres. HTFs are unsuitable for such applications. These heat transfer
fluids are frequently handled at temperatures exceeding their flash point,
making them subject to the "Dangerous Substances and Explosive
Atmosphere" Regulations 2002 (DSEAR). Furthermore, HTFs based on mineral
oils undergo degradation over time, which can lead to a decrease in their flash
point. Consequently, thermal fluids that were initially non-flammable at
operating temperatures can become flammable as time passes. Additionally, these
thermal fluids can generate explosive mist atmospheres when handled under
pressure, even at temperatures below the flash point. Strict procedural control
is necessary for changing the HTF and eliminating lower flash point components
to mitigate the risk of explosions. Regular thermal tests can help minimize the
level of risk; however, without stringent testing and timely inspections, the
potential for these hazards remains inevitable. As a result, the existence of
fire and explosion risks posed by heat transfer fluids impedes their widespread
utilization.
Ecosystem of Heat Transfer Fluids Market
Synthetic fluids emerged as the most widely consumed
product type in the HTF market in the previous year. These fluids offer several
advantages over mineral oils, including resistance to oxidation, thermal
breakdown, and oil sludge problems. They also help reduce evaporation losses
and possess a consistent molecular structure with strong bonds, making them
thermally stable and durable. Furthermore, synthetic fluids have an increased
viscosity index and produce less oil waste, making them environmentally
friendly. However, their higher cost compared to mineral oils is a notable
factor to consider. The fastest-growing category in the HTF market is
glycol-based heat transfer fluids. These fluids exhibit excellent antifreeze
properties and are expected to achieve a compound annual growth rate (CAGR) of
5.6% during the forecast period. Bio-based glycols, which are compatible with
both high and low-temperature applications, are gaining increasing significance
as key components in heat transfer fluid formulations.
Mineral oils are commonly used in various portable
radiator heaters, which find widespread applications in both commercial and
residential settings. These oils exhibit high resistance to chemical oxidation
and thermal cracking while being non-toxic and non-corrosive. They possess high
thermal conductivity and specific heat, enabling efficient heat transfer.
Although mineral oils are utilized in multiple heat transfer mediums, they tend
to degrade more rapidly when exposed to higher temperatures.
Alkylated aromatic compounds are typically formulated for
closed-loop heating systems based on the Rankine cycle. They are extensively
used in diverse operations such as asphalt plants, gas processing, tank cleaning,
and plastic production. These aromatic HTFs demonstrate excellent fluid and
heat transfer properties for low-temperature applications and can be utilized
in both vapor and liquid phases.
The renewable energy industry is expected to register the
highest CAGR during the forecast period in terms of HTF usage. HTFs play a
crucial role in concentrated solar power (CSP) plants, biodiesel production
systems, wind turbines, and geothermal systems. They are also utilized for
energy storage from sunlight, enabling consistent power provision even during
periods of intermittent sunlight. Government regulations promoting clean energy
and the growing demand for solar energy are anticipated to drive the growth of
HTFs in the renewable energy industry.
Last year, the oil and gas segment emerged as the
second-largest market segment, capturing a revenue share of 21.2%. This segment
relies on specific heat transfer fluids tailored to desired temperatures and
compatibility. Heat transfer fluids find applications in various processes such
as recycling, production, refining, and transportation within the oil and gas
sector. Offshore platforms utilize heat transfer liquids in the aqueous phase
for glycol regeneration and facility heating, aiding in the removal of water from
produced natural gas.
In the chemical industry, heat transfer fluids or steam
are used in reboilers, which act as heat exchangers to provide heat to the
bottoms of distillation columns. Reboilers facilitate the vaporization of
liquids from the bottom of the distillation column, generating vapors essential
for driving the distillation column separation process. These products also
find applications in components like tubes, pipes, bushes, and gaskets used for
conveying chemicals, fluids, and acids due to their inertness and high thermal
stability.
The HVAC and refrigeration industry utilizes HTFs as
coolants. However, the sector has been impacted by the slowdown of large-scale
projects in hotels, resorts, office buildings, restaurants, shopping malls, and
entertainment facilities caused by the pandemic. Consequently, the sales of
commercial air conditioners, including packaged air conditioners and variable
refrigerant flow (VRF) air conditioners, have declined. This decrease in demand
from the HVAC and refrigeration industry is expected to have a negative impact
on the market's growth in the near future.
Market Segmentation
For the purpose of this report, the global heat
transfer fluids market segmented on the basis of product, end user, and region:
Product Outlook:
On the basis of product, the market is segmented into glycol-based
fluids, mineral oils, synthetic fluids.
End User Outlook:
On the basis of end user, the market is
segmented into chemical, automotive, gas, HVAC, oil, others, petrochemical,
pharmaceutical renewable energy.
Figure 1 Heat Transfer Fluids Market By End User (Market Size And
Forecast By Value - USD Million, 2022 & 2030)
Regional Outlook (Revenue, USD Million; 2022 & 2030)
Regional Outlook (Revenue, USD Million; 2020-2030) |
|
North America |
U.S. |
Canada |
|
Europe |
Germany |
U.K. |
|
France |
|
Spain |
|
Italy |
|
Rest of the Europe |
|
Asia Pacific |
India |
Japan |
|
China |
|
South Korea |
|
Australia |
|
Rest of Asia-Pacific |
|
Middle East & Africa |
UAE |
Saudi Arabia |
|
South Africa |
|
Rest of Middle East &
Africa |
|
Latin America |
Brazil |
Mexico |
|
Argentina |
|
Rest of Latin America |
Figure 2 Heat Transfer Fluids Market: Regional Dynamics
Asia Pacific is poised to achieve the highest
compound annual growth rate (CAGR) during the forecast period in the heat
transfer fluid (HTF) market. This region, known as a key market for HTFs, is
anticipated to exhibit a CAGR of 11.9% in terms of value. The attractiveness of
Asia Pacific stems from factors such as the availability of low-cost raw
materials and labor, as well as the escalating domestic demand, which
incentivizes HTF manufacturers to invest in the region. The population growth,
rapid industrialization, and the emphasis placed by countries like India and
China on energy infrastructure development contribute significantly to the
projected growth of the HTF market in this region.
The United States plays a pivotal role in the
global installed capacity of concentrated solar power (CSP). In order to
optimize power output during peak demand periods, the country strategically
employs CSP units. Heat transfer fluids are recognized as vital components in
enhancing the efficiency of concentrated solar power plants. They facilitate
the collection of energy from the solar field and its transportation to the
energy storage systems. This stored energy is later utilized for electricity
generation, even during periods of low sunlight or cloudy weather conditions.
Compared to photovoltaic (PV) systems, CSP plants can offer an additional six
hours of storage capacity, resulting in an operational value of USD 35.8/MWh.
The expanding scope of CSP, along with its competitive advantages over other
renewable energy sources, has led to substantial growth and significant
adoption of heat transfer fluids in this segment.
Heat transfer fluids also find applications
in the oil and gas industry, which is a vital contributor to the U.S. economy.
With shale resource development projected to increase liquids and natural gas
production in the foreseeable future, the demand for heat transfer fluids is
expected to receive a boost.
The chemical industry in Mexico has
experienced notable investments and a consistent supply of diverse raw
materials, bolstering its foundation. Rapid industrialization, coupled with
increased chemical exports to NAFTA countries, is anticipated to drive the
demand for heat transfer fluids in Mexico. Additionally, the country has a
strong presence in the plastic manufacturing industry.
Companies Considered And Profiled In This Market Study
The players operating in the market have
undertaken several strategies related to the market in the period 2020-2022.
some of the prominent players in the Heat Transfer Fluids Market include
·
THE DOW CHEMICAL COMPANY
·
EASTMAN CHEMICAL
COMPANY
·
EXXONMOBIL
·
CHEVRON
·
HUNTSMAN
CORPORATION
·
SHELL PLC
·
LANXESS
·
CLARIANT AG
·
WACKER CHEMIE AG
·
INDIAN OIL
CORPORATION
·
SCHULTZ CANADA
CHEMICALS LTD.
·
PARATHERM
·
ARKEMA
·
BASF
·
DALIAN RICHFORTUNE
CHEMICALS
·
BRITISH PETROLEUM
·
DUPONT TATE &
LYLE
·
DYNALENE
·
HINDUSTAN PETROLEUM
CORPORATION
·
GLOBAL HEAT
TRANSFER
·
ISEL
·
PARAS LUBRICANTS
LIMITED
·
PETRO-CANADA
·
PHILLIPS 66
·
RADCO INDUSTRIES
·
SCHAEFFER
SPECIALIZED LUBRICANTS
·
DELTA WESTERN, INC.
(DWI)
·
DOW CHEMICALS
·
GJ CHEMICAL
·
KOST USA, Inc.
Global Heat Transfer Fluids Market Report Scope
Historical data |
2020 - 2022 |
Base year for estimation |
2022 |
Forecast period |
2023 - 2030 |
Market size value in 2022 |
USD 4.12 Billion |
Revenue forecast in 2030 |
USD 8.15 billion |
Growth Rate |
CAGR of 8.9 % from 2023 to 2030 |
Quantitative units |
Revenue in USD Million/Billion & CAGR from 2023 to 2030 |
Report coverage |
Revenue forecast, company share,
competitive landscape, growth factors, and trends |
Segments covered |
Product, End User |
Key companies profiled |
The Dow Chemical Company, Eastman Chemical
Company, ExxonMobil |
Regional Scope |
North America, Europe, Asia Pacific, Middle East & Africa, Latin
America |
Country Scope |
U.S., Canada, Germany, U.K., France, Italy,
Spain, India, Japan, China, Australia, South Korea, Saudi Arabia, UAE, South
Africa, Brazil, Mexico, Argentina |
Customization scope |
Free report customization (equivalent to up to 8 analysts’ working
days) with purchase. Addition or alteration to country, regional &
segment scope. |
Product Outlook (Revenue,
USD Million/Billion; 2020-2030)
·
Glycol-based Fluids
·
Mineral Oils
·
Others
·
Synthetic Fluids
End User Outlook
(Revenue, USD Million/Billion; 2020-2030)
·
Chemical
·
Automotive
·
Gas
·
HVAC
·
Oil
·
Others
·
Petrochemical
·
Pharmaceutical
·
Renewable Energy
Regional Outlook (Revenue,
USD Million/Billion; 2020-2030)
·
North America
o
U.S.
o
Canada
·
Europe
o
Germany
o
U.K.
o
France
o
Spain
o
Italy
o
Rest of the Europe
·
Asia Pacific
o
India
o
Japan
o
China
o
South Korea
o
Australia
o
Rest of Asia-Pacific
·
Middle East &
Africa
o
UAE
o
Saudi Arabia
o
South Africa
o
Rest of Middle East
& Africa
·
Latin America
o
Brazil
o
Mexico
o
Argentina
o
Rest of Latin
America
Recent Developments In Heat Transfer Fluids Market:
In 2021, Company A, a leading manufacturer of
heat transfer fluids, announced its acquisition by Company B, a global
conglomerate specializing in energy solutions. This strategic move allowed
Company B to expand its portfolio and strengthen its position in the heat
transfer fluids market. The acquisition aimed to leverage Company A's expertise
and product offerings to meet the increasing demand for energy-efficient
solutions.
During the same year, Company C, a key player
in the heat transfer fluid industry, formed a partnership with Company D, a renowned
renewable energy company. The partnership focused on developing innovative heat
transfer fluids specifically tailored for use in solar thermal power plants. By
combining their expertise and resources, the two companies aimed to enhance the
efficiency and performance of solar energy systems, further promoting the
adoption of renewable energy sources.
In 2020, Company E, a prominent provider of
specialty chemicals, announced the acquisition of Company F, a well-established
manufacturer of heat transfer fluids. The acquisition enabled Company E to
expand its product portfolio and strengthen its presence in the heat transfer
fluids market. It also allowed Company E to leverage Company F's extensive
customer base and distribution network, facilitating increased market
penetration and growth opportunities.
Another significant partnership occurred in
2019 when Company G, a leading chemical company, joined forces with Company H,
a major renewable energy player. The partnership aimed to develop advanced heat
transfer fluids for geothermal energy applications. By combining their research
and development capabilities, the two companies aimed to create
high-performance heat transfer fluids that would optimize energy conversion and
enhance the overall efficiency of geothermal power generation.
Company K, a leading manufacturer of heat
transfer fluids, announced a strategic partnership with Company L, a
technology-driven energy solutions provider. The partnership aims to develop
advanced heat transfer fluids specifically designed for electric vehicle (EV)
battery thermal management systems. The collaboration will leverage Company K's
expertise in heat transfer fluid formulation and Company L's experience in EV
technologies to enhance battery efficiency and prolong battery life.
In a major acquisition, Company M, a global
chemical company, completed the purchase of Company N, a specialized heat
transfer fluid manufacturer. The acquisition enables Company M to broaden its
product portfolio in the energy sector and strengthen its position as a key
supplier of heat transfer fluids. The move aligns with Company M's strategy to
meet the growing demand for sustainable and high-performance solutions in the
renewable energy and industrial sectors.
Company O, a renewable energy company,
announced a joint venture with Company P, a leading heat transfer fluid
supplier, to develop and commercialize next-generation thermal energy storage
systems. The partnership aims to optimize the storage and utilization of
renewable energy by leveraging innovative heat transfer fluids and advanced
storage technologies. The collaboration seeks to address the challenges
associated with intermittent renewable energy sources and enhance grid
stability.
Company Q, a prominent player in the heat
transfer fluid industry, entered into a merger agreement with Company R, a
global energy services provider. The merger aims to create a vertically
integrated company that offers comprehensive solutions for energy efficiency
and renewable energy applications. The combined entity will leverage synergies
between their respective product portfolios and enhance their ability to serve
customers across multiple industries.
Company S, a leading manufacturer of
specialty chemicals, announced the acquisition of Company T, a specialized heat
transfer fluid technology company. The acquisition strengthens Company S's
position in the heat transfer fluids market by adding T's innovative product
line and technical expertise. The move reflects Company S's commitment to
investing in advanced technologies that promote energy efficiency and
sustainability.
Additionally, in 2018, Company I, a global
leader in energy solutions, completed the acquisition of Company J, a
specialized manufacturer of heat transfer fluids. The acquisition aligned with
Company I's strategy to strengthen its position in the renewable energy sector
and expand its product offerings. By integrating Company J's heat transfer
fluid expertise into its portfolio, Company I aimed to provide comprehensive
solutions to meet the evolving needs of the renewable energy market.
Heat transfer fluids play a critical role in
enhancing the efficiency of heat transfer processes in various industries.
Understanding the top impacting factors, such as thermal stability, heat
transfer efficiency, environmental impact, and compatibility with materials, is
essential for selecting appropriate HTFs. Additionally, government policies and
regulations further contribute to the sustainable use of HTFs by promoting
environmental consciousness and safety standards. By considering these factors
and embracing sustainable practices, industries can optimize their operations
while minimizing their environmental footprint.
Chapter
1. Introduction |
|
1.1. Market Definition |
|
1.2. Research Scope |
|
1.2.1. Markets Covered |
|
1.2.2. Years Considered for
Study |
|
Chapter
2. Executive Summary |
|
2.1. Summary Snapshot Market Size
and Forecast, 2020-2030 |
|
2.2. Heat Transfer Fluids Market Share by
Product, 2022 vs 2030 (USD Million) |
|
2.3. Heat Transfer Fluids Market Share
by End User, 2022 vs 2030 (USD Million) |
|
2.4. Heat Transfer Fluids Market Share
by Region, 2022 vs 2030 (USD Million) |
|
Chapter
3. Key Insights |
|
Chapter
4. Heat Transfer Fluids Market Segmentation & Impact Analysis |
|
4.1. Heat Transfer Fluids Market
Indicators Analysis |
|
4.1.1. Market Drivers
Analysis |
|
4.1.1.1. Rapid industrialization
and supportive renewable energy policies in Asia Pacific |
|
4.1.1.2. Growing
number of concentrating solar power projects |
|
4.1.1.3.
Increased use of HTFs to reduce operating costs and save energy |
|
4.1.2. Market Restraint
Analysis |
|
4.1.2.1. Volatile
raw material prices |
|
4.1.3. Market Opportunity
Analysis |
|
4.1.3.1. Increasing
need for energy conservation and clean energy |
|
4.1.3.2. Government
schemes focused on energy efficiency and renewable energy |
|
4.2. Regulatory Analysis |
|
4.2.1. North America |
|
4.2.1.1. U.S. |
|
4.2.1.2. Canada |
|
4.2.2. Europe |
|
4.2.3. Asia Pacific |
|
4.2.3.1. India |
|
4.2.3.2. Japan |
|
4.2.3.3. China |
|
4.3. Technological Insights |
|
4.4. COVID-19 Impact analysis on Heat
Transfer Fluids Market |
|
4.5. Porter’s Five Forces Analysis |
|
4.5.1. Bargaining Power of
Buyers/Consumers |
|
4.5.2. Bargaining Power of
Suppliers |
|
4.5.3. Threat of New Entrants |
|
4.5.4. Threat of Substitute
Products |
|
4.5.5. Intensity of Competitive
Rivalry |
|
4.6. Competitive Metric Space Analysis |
|
Chapter
5. Heat Transfer Fluids Market, By Product (Market Size and Forecast by
Value - USD Million, 2020 - 2030) |
|
5.1. Heat Transfer Fluids Market, By
Product (Market Size and Forecast by Value - USD Million, 2022 & 2030) |
|
5.1.1. Glycol-based Fluids |
|
5.1.1.1. Glycol-based Fluids Market Estimates and
Forecast, 2020-2030 (USD Million) |
|
5.1.1.2. Glycol-based Fluids Market Estimates and
Forecast, By Region, 2020-2030 (USD Million) |
|
5.1.2. Mineral Oils |
|
5.1.2.1. Mineral
Oils Market Estimates and Forecast, 2020-2030 (USD Million) |
|
5.1.2.2. Mineral
Oils Market Estimates and Forecast, By Region, 2020-2030 (USD Million) |
|
5.1.3. Synthetic Fluids |
|
5.1.3.1. Synthetic
Fluids Market Estimates and Forecast, 2020-2030 (USD Million) |
|
5.1.3.2. Synthetic
Fluids Market Estimates and Forecast, By Region, 2020-2030 (USD Million) |
|
5.1.4. Others |
|
5.1.4.1. Others
Market Estimates and Forecast, 2020-2030 (USD Million) |
|
5.1.4.2. Others
Market Estimates and Forecast, By Region, 2020-2030 (USD Million) |
|
Chapter
6. Heat Transfer Fluids Market, By End User (Market Size and Forecast by
Value - USD Million, 2020 - 2030) |
|
6.1. Heat Transfer Fluids Market, By End
User (Market Size and Forecast by Value - USD Million, 2022 & 2030) |
|
6.1.1. Chemical |
|
6.1.1.1. Chemical Market Estimates and Forecast,
2020-2030 (USD Million) |
|
6.1.1.2. Chemical Market Estimates and Forecast, By
Region, 2020-2030 (USD Million) |
|
6.1.2. Automotive |
|
6.1.2.1. Automotive Market Estimates and Forecast,
2020-2030 (USD Million) |
|
6.1.2.2. Automotive Market Estimates and Forecast,
By Region, 2020-2030 (USD Million) |
|
6.1.3. Gas |
|
6.1.3.1. Gas Market
Estimates and Forecast, 2020-2030 (USD Million) |
|
6.1.3.2. Gas Market Estimates
and Forecast, By Region, 2020-2030 (USD Million) |
|
6.1.4. HVAC |
|
6.1.4.1. HVAC Market
Estimates and Forecast, 2020-2030 (USD Million) |
|
6.1.4.2. HVAC Market
Estimates and Forecast, By Region, 2020-2030 (USD Million) |
|
6.1.5. Oil |
|
6.1.5.1. Oil Market
Estimates and Forecast, 2020-2030 (USD Million) |
|
6.1.5.2. Oil Market
Estimates and Forecast, By Region, 2020-2030 (USD Million) |
|
6.1.6. Others |
|
6.1.6.1. Others
Market Estimates and Forecast, 2020-2030 (USD Million) |
|
6.1.6.2. Others Market
Estimates and Forecast, By Region, 2020-2030 (USD Million) |
|
6.1.7. Petrochemical |
|
6.1.7.1.
Petrochemical Market Estimates and Forecast, 2020-2030 (USD Million) |
|
6.1.7.2.
Petrochemical Market Estimates and Forecast, By Region, 2020-2030 (USD
Million) |
|
6.1.8. Pharmaceutical |
|
6.1.8.1.
Pharmaceutical Market Estimates and Forecast, 2020-2030 (USD Million) |
|
6.1.8.2. Pharmaceutical
Market Estimates and Forecast, By Region, 2020-2030 (USD Million) |
|
6.1.9. Renewable Energy |
|
6.1.9.1. Renewable Energy
Market Estimates and Forecast, 2020-2030 (USD Million) |
|
6.1.9.2. Renewable
Energy Market Estimates and Forecast, By Region, 2020-2030 (USD Million) |
|
Chapter
7. Heat Transfer Fluids Market, By Region (Market Size and Forecast by Value
- USD Million, 2020 - 2030) |
|
7.1. Heat Transfer Fluids Market, By
Region (Market Size and Forecast by Value - USD Million, 2022 & 2030) |
|
7.2. North America |
|
7.2.1. North America Heat
Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.2.2. North America Heat
Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.2.5. North America Heat
Transfer Fluids Market, By Country, 2020-2030 (USD Million) |
|
7.2.6. U.S. |
|
7.2.6.1. U.S.
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.2.6.2. U.S.
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.2.7. Canada |
|
7.2.7.1. Canada
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.2.7.2. Canada
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.3. Europe |
|
7.3.1. Europe Heat Transfer Fluids
Market, By Product, 2020-2030 (USD Million) |
|
7.3.2. Europe Heat Transfer
Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.3.5. Europe Heat Transfer Fluids
Market, By Country, 2020-2030 (USD Million) |
|
7.3.6. Germany |
|
7.3.6.1. Germany
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.3.6.2. Germany
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.3.7. U.K. |
|
7.3.7.1. U.K.
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.3.7.2. U.K.
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.3.8. France |
|
7.3.8.1. France
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.3.8.2. France Heat
Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.3.9. Spain |
|
7.3.9.1. Spain
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.3.9.2. Spain
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.3.10. Italy |
|
7.3.10.1. Italy
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.3.10.2. Italy
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.3.11. Rest of Europe |
|
7.3.11.1. Rest of
Europe Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.3.11.2. Rest of
Europe Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.4. Asia Pacific |
|
7.4.1. Asia Pacific Heat
Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.4.2. Asia Pacific Heat
Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.4.5. Asia Pacific Heat
Transfer Fluids Market, By Country, 2020-2030 (USD Million) |
|
7.4.6. India |
|
7.4.6.1. India
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.4.6.2. India Heat
Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.4.7. Japan |
|
7.4.7.1. Japan
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.4.7.2. Japan
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.4.8. China |
|
7.4.8.1. China
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.4.8.2. China
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.4.9. South Korea |
|
7.4.9.1. South Korea
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.4.9.2. South
Korea Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.4.10. Australia |
|
7.4.10.1.
Australia Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.4.10.2.
Australia Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.4.11. Rest of Asia Pacific |
|
7.4.11.1. Rest of Asia
Pacific Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.4.11.2. Rest of
Asia Pacific Heat Transfer Fluids Market, By End User, 2020-2030 (USD
Million) |
|
7.5. Middle East & Africa |
|
7.5.1. Middle East & Africa
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.5.2. Middle East & Africa
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.5.5. Middle East & Africa Heat
Transfer Fluids Market, By Country, 2020-2030 (USD Million) |
|
7.5.6. UAE |
|
7.5.6.1. UAE Heat
Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.5.6.2. UAE Heat Transfer Fluids
Market, By End User, 2020-2030 (USD Million) |
|
7.5.7. Saudi Arabia |
|
7.5.7.1. Saudi
Arabia Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.5.7.2. Saudi Arabia Heat
Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.5.8. South Africa |
|
7.5.8.1. South
Africa Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.5.8.2. South
Africa Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.5.7. Rest of Middle East
& Africa |
|
7.5.7.1. Rest of
Middle East & Africa Heat Transfer Fluids Market, By Product, 2020-2030
(USD Million) |
|
7.5.7.2. Rest of
Middle East & Africa Heat Transfer Fluids Market, By End User, 2020-2030
(USD Million) |
|
7.6. Latin America |
|
7.6.1. Latin America Heat
Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.6.2. Latin America Heat
Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.6.5. Latin America Heat
Transfer Fluids Market, By Country, 2020-2030 (USD Million) |
|
7.6.6. Brazil |
|
7.6.6.1. Brazil
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.6.6.2. Brazil Heat
Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.6.7. Mexico |
|
7.6.7.1. Mexico
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.6.7.2. Mexico
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
|
7.6.8. Argentina |
|
7.6.8.1.
Argentina Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.6.8.2. Argentina Heat Transfer Fluids
Market, By End User, 2020-2030 (USD Million) |
|
7.6.7. Rest of Latin America |
|
7.6.7.1. Rest of
Latin America Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
|
7.6.7.2. Rest of
Latin America Heat Transfer Fluids Market, By End User, 2020-2030 (USD
Million) |
|
Chapter
8. Competitive Landscape |
|
8.1. Market Revenue Share by
Manufacturers |
|
8.2. Competitor’s Positioning |
|
8.3. Strategy Benchmarking |
|
8.3.1. Partnership &
Agreement |
|
8.3.2. New Product Development |
|
8.3.3. Mergers &
Acquisitions |
|
8.3.4. Investment &
Expansion |
|
8.4. Vendor Landscape |
|
8.4.1. Distributors |
|
8.4.2. North America |
|
8.4.3. Europe |
|
8.4.4. Asia Pacific |
|
8.4.5. Middle East &
Africa |
|
8.4.6. Latin America |
|
8.5. Zettabyte Analytics Insights for
Competitive Landscape |
|
Chapter
9. Company Profiles |
|
9.1. Arkema |
|
9.1.1. Company Overview |
|
9.1.2. Products Offered |
|
9.1.3. Financials |
|
9.1.4. Recent Development |
|
9.2. Basf |
|
9.2.1. Company Overview |
|
9.2.2. Products Offered |
|
9.2.3. Financials |
|
9.2.4. Recent Development |
|
9.3. British Petroleum |
|
9.3.1. Company Overview |
|
9.3.2. Products Offered |
|
9.3.3. Financials |
|
9.3.4. Recent Development |
|
9.4. Chevron |
|
9.4.1. Company Overview |
|
9.4.2. Products Offered |
|
9.4.3. Financials |
|
9.4.4. Recent Development |
|
9.5. Clariant Ag |
|
9.5.1. Company Overview |
|
9.5.2. Products Offered |
|
9.5.3. Financials |
|
9.5.4. Recent Development |
|
9.6. Dalian Richfortune Chemicals |
|
9.6.1. Company Overview |
|
9.6.2. Products Offered |
|
9.6.3. Financials |
|
9.6.4. Recent Development |
|
9.7. Delta Western, Inc. (Dwi) |
|
9.7.1. Company Overview |
|
9.7.2. Products Offered |
|
9.7.3. Financials |
|
9.7.4. Recent Development |
|
9.8. Dow Chemicals |
|
9.8.1. Company Overview |
|
9.8.2. Products Offered |
|
9.8.3. Financials |
|
9.8.4. Recent Development |
|
9.9. Dupont Tate & Lyle |
|
9.9.1. Company Overview |
|
9.9.2. Products Offered |
|
9.9.3. Financials |
|
9.9.4. Recent Development |
|
9.10. Dynalene |
|
9.10.1. Company Overview |
|
9.10.2. Products Offered |
|
9.10.3. Financials |
|
9.10.4. Recent
Development |
|
9.11. Eastman Chemical Company |
|
9.11.1. Company Overview |
|
9.11.2. Products Offered |
|
9.11.3. Financials |
|
9.11.4. Recent
Development |
|
9.12. Exxonmobil |
|
9.12.1. Company Overview |
|
9.12.2. Products Offered |
|
9.12.3. Financials |
|
9.12.4. Recent
Development |
|
9.13. Gj Chemical |
|
9.13.1. Company Overview |
|
9.13.2. Products Offered |
|
9.13.3. Financials |
|
9.13.4. Recent
Development |
|
9.14. Global Heat Transfer |
|
9.14.1. Company Overview |
|
9.14.2. Products Offered |
|
9.14.3. Financials |
|
9.14.4. Recent
Development |
|
9.15. Hindustan Petroleum Corporation |
|
9.15.1. Company Overview |
|
9.15.2. Products Offered |
|
9.15.3. Financials |
|
9.15.4. Recent
Development |
|
9.16. Huntsman Corporation |
|
9.16.1. Company Overview |
|
9.16.2. Products Offered |
|
9.16.3. Financials |
|
9.16.4. Recent
Development |
|
9.17. Indian Oil Corporation |
|
9.17.1. Company Overview |
|
9.17.2. Products Offered |
|
9.17.3. Financials |
|
9.17.4. Recent Development |
|
9.18. Isel |
|
9.18.1. Company Overview |
|
9.18.2. Products Offered |
|
9.18.3. Financials |
|
9.18.4. Recent
Development |
|
9.19. Kost Usa, Inc |
|
9.19.1. Company Overview |
|
9.19.2. Products Offered |
|
9.19.3. Financials |
|
9.19.4. Recent
Development |
|
9.20. Lanxess |
|
9.20.1. Company Overview |
|
9.20.2. Products Offered |
|
9.20.3. Financials |
|
9.20.4. Recent
Development |
|
9.21. Paras Lubricants Limited |
|
9.21.1. Company Overview |
|
9.21.2. Products Offered |
|
9.21.3. Financials |
|
9.21.4. Recent
Development |
|
9.22. Paratherm |
|
9.22.1. Company Overview |
|
9.22.2. Products Offered |
|
9.22.3. Financials |
|
9.22.4. Recent
Development |
|
9.23. Petro-Canada |
|
9.23.1. Company Overview |
|
9.23.2. Products Offered |
|
9.23.3. Financials |
|
9.23.4. Recent
Development |
|
9.24. Phillips 66 |
|
9.24.1. Company Overview |
|
9.24.2. Products Offered |
|
9.24.3. Financials |
|
9.24.4. Recent
Development |
|
9.25. Radco Industries |
|
9.25.1. Company Overview |
|
9.25.2. Products Offered |
|
9.25.3. Financials |
|
9.25.4. Recent
Development |
|
9.26. Schaeffer Specialized Lubricants |
|
9.26.1. Company Overview |
|
9.26.2. Products Offered |
|
9.26.3. Financials |
|
9.26.4. Recent
Development |
|
9.27. Schultz Canada Chemicals Ltd. |
|
9.27.1. Company Overview |
|
9.27.2. Products Offered |
|
9.27.3. Financials |
|
9.27.4. Recent
Development |
|
9.28. Shell Plc |
|
9.28.1. Company Overview |
|
9.28.2. Products Offered |
|
9.28.3. Financials |
|
9.28.4. Recent
Development |
|
9.29. The Dow Chemical Company |
|
9.29.1. Company Overview |
|
9.29.2. Products Offered |
|
9.29.3. Financials |
|
9.29.4. Recent
Development |
|
9.30. Wacker Chemie Ag |
|
9.30.1. Company Overview |
|
9.30.2. Products Offered |
|
9.30.3. Financials |
|
9.30.4. Recent
Development |
|
Chapter
10. Research Methodology |
|
10.1. Research Sources |
|
10.1.1. Primary |
|
10.1.2. Secondary |
|
10.10. Market Size Estimation |
|
Chapter
11. Appendix |
|
11.1.
Discussion guide |
|
11.2.
Knowledge Store: Zettabyte Analytics Subscription Portal |
|
11.3.
Available Customizations |
|
11.4. Associated
Zettabyte Analytics Reports |
|
List of
Tables |
|
Table 1 |
Heat
Transfer Fluids Market, By Product (Market Size and Forecast by Value - USD
Million, 2022 & 2030) |
Table 2 |
Glycol-based
Fluids Market Estimates and Forecast, 2020-2030 (USD Million) |
Table 3 |
Glycol-based
Fluids Market Estimates and Forecast, By Region, 2020-2030 (USD Million) |
Table 4 |
Mineral
Oils Market Estimates and Forecast, 2020-2030 (USD Million) |
Table 5 |
Mineral
Oils Market Estimates and Forecast, By Region, 2020-2030 (USD Million) |
Table 6 |
Heat
Transfer Fluids Market, By End User (Market Size and Forecast by Value - USD
Million, 2022 & 2030) |
Table 7 |
Chemical
Market Estimates and Forecast, By Region, 2020-2030 (USD Million) |
Table 8 |
North
America Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 9 |
North
America Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 10 |
North
America Heat Transfer Fluids Market, By Country, 2020-2030 (USD Million) |
Table 11 |
U.S. Heat
Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 12 |
U.S. Heat
Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 13 |
Canada
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 14 |
Canada
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 15 |
Europe
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 16 |
Europe
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 17 |
Europe
Heat Transfer Fluids Market, By Country, 2020-2030 (USD Million) |
Table 18 |
Germany
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 19 |
Germany
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 20 |
U.K. Heat
Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 21 |
U.K. Heat
Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 22 |
France
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 23 |
France
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 24 |
Spain
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 25 |
Spain
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 26 |
Italy
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 27 |
Italy
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 28 |
Rest of
Europe Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 29 |
Rest of
Europe Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 30 |
Asia
Pacific Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 31 |
Asia
Pacific Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 32 |
Asia
Pacific Heat Transfer Fluids Market, By , 2020-2030 (USD Million) |
Table 33 |
India
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 34 |
India
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 35 |
Japan
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 36 |
Japan
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 37 |
China
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 38 |
China
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 39 |
South
Korea Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 40 |
South
Korea Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 41 |
Australia
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 42 |
Australia
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 43 |
Rest of
Asia Pacific Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 44 |
Rest of
Asia Pacific Heat Transfer Fluids Market, By End User, 2020-2030 (USD
Million) |
Table 45 |
Middle
East & Africa Heat Transfer Fluids Market, By Product, 2020-2030 (USD
Million) |
Table 46 |
Middle
East & AfricaHeat Transfer Fluids Market, By End User, 2020-2030 (USD
Million) |
Table 47 |
Middle
East & Africa Heat Transfer Fluids Market, By Country, 2020-2030 (USD
Million) |
Table 48 |
UAE Heat
Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 49 |
UAE Heat
Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 50 |
Saudi
Arabia Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 51 |
Saudi
Arabia Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 52 |
South
Africa Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 53 |
South
Africa Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 54 |
Rest of
Middle East & Africa Heat Transfer Fluids Market, By Product, 2020-2030
(USD Million) |
Table 55 |
Rest of
Middle East & Africa Heat Transfer Fluids Market, By End User, 2020-2030
(USD Million) |
Table 56 |
Latin
America Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 57 |
Latin
America Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 58 |
Latin
America Heat Transfer Fluids Market, By Country, 2020-2030 (USD Million) |
Table 59 |
Brazil
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 60 |
Brazil
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 61 |
Mexico
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 62 |
Mexico
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 63 |
Argentina
Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 64 |
Argentina
Heat Transfer Fluids Market, By End User, 2020-2030 (USD Million) |
Table 65 |
Rest of
Latin America Heat Transfer Fluids Market, By Product, 2020-2030 (USD Million) |
Table 66 |
Rest of
Latin America Heat Transfer Fluids Market, By End User, 2020-2030 (USD
Million) |
Table 67 |
Product
Launch & Development in The Heat Transfer Fluids Market, 2020-2022 |
Table 68 |
Investment
and Expansion in The Heat Transfer Fluids Market, 2020-2022 |
Table 69 |
Partnership
& Collaboration in The Heat Transfer Fluids Market, 2020-2022 |
Table 70 |
Merger
& Acquisition in The Heat Transfer Fluids Market, 2020-2022 |
List of
Figures |
|
Figure 1 |
Research
Methodology |
Figure 2 |
Summary
Snapshot Market Size and Forecast, USD Million, 2022 & 2030 |
Figure 3 |
Global
Heat Transfer Fluids Market Segmentation & Impact Analysis |
Figure 4 |
Regulatory
Analysis |
Figure 5 |
COVID-19
Impact analysis on Heat Transfer Fluids Market |
Figure 6 |
Market
Revenue Share by Manufacturers |
Figure 7 |
Heat
Transfer Fluids Market, By Product (Market Size and Forecast by Value - USD
Million, 2022 & 2030) |
Figure 8 |
Heat
Transfer Fluids Market, By End User (Market Size and Forecast by Value - USD
Million, 2022 & 2030) |
Figure 9 |
Heat
Transfer Fluids Market, By Region (Market Size and Forecast by Value - USD
Million, 2022 & 2030) |
1.
Research Sources
We at Zettabyte Analytics have a
detailed and related research methodology focussed on estimating the market
size and forecasted value for the given market. Comprehensive research
objectives and scope were obtained through secondary research of the parent and
peer markets. The next step was to validate our research by various market
models and primary research. Both top-down and bottom-up approaches were
employed to estimate the market. In addition to all the research reports, data
triangulation is one of the procedures used to evaluate the market size of
segments and sub-segments.
Research Methodology
1.1. Secondary Research
The secondary research study involves various sources and databases used
to analyze and collect information for the market-oriented survey of a specific
market. We use multiple databases for our exhaustive secondary research, such
as Factiva, Dun & Bradstreet, Bloomberg, Research article, Annual reports,
Press Release, and SEC filings of significant companies. Apart from this, a
dedicated set of teams continuously extracts data of key industry players and
makes an extensive and unique segmentation related to the latest market
development.
1.2. Primary Research
The primary research includes gathering data from specific domain
experts through a detailed questionnaire, emails, telephonic interviews, and
web-based surveys. The primary interviewees for this study include an expert
from the demand and supply side, such as CEOs, VPs, directors, sales heads, and
marketing managers of tire 1,2, and 3 companies across the globe.
1.3. Data Triangulation
The data triangulation is very important for any market study, thus we
at Zettabyte Analytics focus on at least three sources to ensure a high level
of accuracy. The data is triangulated by studying various factors and trends
from both supply and demand side. All the reports published and stored in our
repository follows a detailed process to obtain a reliable insight for our
clients.
1.4. In-House Verification
To validate the segmentation
and verify the data collected, our market expert ensures whether our research
analyst is considering fine distinction before analyzing the market.
1.5. Reporting
In the end,
presenting our research reports complied in a different format for straightforward
valuation such as ppt, pdf, and excel data pack is done.
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