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市場調查報告書
商品編碼
1403540
氣體分離市場至2030年的預測:按氣體類型、設備、技術、應用、最終用戶和地區的全球分析Gas Separation Market Forecasts to 2030 - Global Analysis By Gas Type, Equipment, Technology, Application, End User and By Geography |
根據 Stratistics MRC 的資料,2023年全球氣體分離市場規模為 144 億美元,預計預測期內年複合成長率為 5.9%,到2030年將達到 215.1 億美元。
氣體分離是包括精製單一氣體或從混合物中分離氣體的基本過程。這項重要技術應用於多種產業,包括醫療保健、環境保護、能源生產和工業製造。此外,氣體分離方法包括適合特定應用的多種方法。這些包括膜分離、吸附、蒸餾和低溫過程。
深冷分離系統的設計計算是根據單位時間處理的氣體量進行的。根據系統設計,給出了熱交換器、冷凝槽和冷箱的結構。
氣體分離市場受到新興國家工業化不斷發展的推動。製造業的各種流程都需要工業氣體,包括電子和汽車產業。此外,這些氣體(主要是氮氣和氧氣)對於焊接、電子組裝和金屬加工非常重要。隨著工廠和製造設施的發展,氣體分離技術可以滿足對可靠、高純度氣體供應不斷成長的需求。
氣體分離的方法很多,特別是蒸餾和低溫分離,需要大量的能量。除了營運成本增加之外,這種高能源消耗還會導致溫室氣體排放,符合永續性目標和環境法規。然而,該行業面臨著平衡減少環境影響的需求與高效氣體分離的需求的挑戰。
氣體分離技術不斷發展,使公司能夠提出創造性的解決方案。透過使用人工智慧和自動化、更好的薄膜材料和更有效的製程設計,氣體分離系統的效率和成本效益提高。此外,這些發展鼓勵使用更環保、更有效的分離技術,同時幫助公司保持競爭力。
必須意識到新技術和氣體分離替代方案所帶來的潛在威脅。傳統的氣體分離方法可能會受到材料科學、製程工程和節能方面進步的挑戰。此外,創新的吸附材料、最先進的薄膜和各種分離技術是一些新興技術的例子,它們可能透過提供負擔得起且永續的解決方案對市場上現有的參與者構成威脅。
COVID-19 的爆發對氣體分離市場產生了各種影響。封鎖和經濟不確定性導致生產和能源消耗受到限制,而工業製造和能源等其他行業則出現混亂和需求減少。由於治療 COVID-19 患者對醫用氣體的需求增加,醫療/保健氣體供應等一些行業的需求增加。此外,由於供應鏈中斷和勞動力流動限制,一些企業面臨營運挑戰,也影響了設備和材料的採購和維護。
天然氣加工業佔最大佔有率。該部門的特點是從原料天然氣中分離和精製氣體,確保其在分配前符合所需的品質標準。天然氣作為一種重要的能源來源,被分離成甲烷、乙烷和丙烷等有價值的成分,並去除二氧化碳、水蒸氣和硫化合物等污染物。這些程序確保各種商業、工業和住宅應用中天然氣供應的安全和品質。
年複合成長率最高的領域是醫療保健,其中氣體分離技術在確保高純度氣體(尤其是氮氣和氧氣)的穩定供應方面發揮著非常重要的作用。此外,這些氣體在許多醫療應用中發揮重要作用,例如麻醉、呼吸治療以及作為設備的載氣。由於全球對患者護理和醫療保健品質的關注以及醫療和保健基礎設施的進步,醫療保健行業對氣體分離解決方案的需求穩步成長。
亞太地區所佔佔有率最大。主要原因是中國、印度等國家的快速都市化和工業化,增加了對工業氣體的需求。此外,能源產業的成長,特別是再生能源和天然氣加工領域的成長,也對該地區的市場主導地位發揮了重要作用。
中東和北非(MENA)地區預計年複合成長率最高。石化等下游產業的擴張以及油氣產業投資的增加是該成長的主要動力。此外,重點將氣體分離技術應用於天然氣加工並提高天然氣生產效率,促進了該地區的快速成長。
According to Stratistics MRC, the Global Gas Separation Market is accounted for $14.40 billion in 2023 and is expected to reach $21.51 billion by 2030 growing at a CAGR of 5.9% during the forecast period. Gas separation is a basic procedure that includes purifying individual gases or separating gases from gas mixtures. This vital technology is used in many different industries, including healthcare, environmental protection, energy production, and industrial manufacturing. Additionally, diverse approaches, each suited to a particular application, are included in gas separation methods. These include membrane separation, adsorption, distillation, and cryogenic processes.
According to the gas quantity processed in per unit time, the design calculation of the cryogenic separation system was carried out. Based on the system design, the heat exchanger, the condensation tank and the cold box structural were all displayed.
The market for gas separation is driven by the unrelenting rate of industrialization in developing countries. Industrial gases are necessary for a number of processes in the manufacturing sector, which includes the electronics and automotive industries. Moreover, these gases, mainly nitrogen and oxygen, are essential for welding, assembling electronics, and fabricating metal. Gas separation technologies can meet the growing demand for reliable, high-purity gas supplies as factories and manufacturing facilities grow.
Numerous methods of gas separation require a lot of energy, particularly distillation and cryogenic separation. Along with raising operating expenses, this high energy use also contributes to greenhouse gas emissions, which is in line with sustainability objectives and environmental regulations. However, the industry faces a challenge in balancing the need for reduced environmental impact with the requirement for efficient gas separation.
Gas separation technologies are always evolving, which gives businesses the chance to come up with creative solutions. The efficiency and cost-effectiveness of gas separation systems are being improved through the use of artificial intelligence and automation, better membrane materials, and more effective process designs. Furthermore, these developments support businesses in maintaining their competitiveness while also encouraging the use of more environmentally friendly and effective separation techniques.
It is imperative to acknowledge the potential threat posed by emerging technologies and alternative methods of gas separation. Conventional gas separation methods could be challenged by advancements in materials science, process engineering, and energy conservation. Moreover, innovative adsorption materials, cutting-edge membranes, and different separation techniques are a few examples of new techniques that could pose a threat to the market's established players by providing affordable and sustainable solutions.
The COVID-19 pandemic affected the gas separation market in a number of ways. While lockdowns and economic uncertainty caused production and energy consumption to be curtailed, other sectors, like industrial manufacturing and energy, saw disruptions and decreased demand. Some segments, like medical and healthcare gas supply, experienced heightened demand due to the increased need for medical gases in treating COVID-19 patients. Additionally, some companies faced operational challenges as a result of supply chain disruptions and restrictions on workforce mobility, which also had an impact on the sourcing and maintenance of equipment and materials.
The Natural Gas Processing segment holds the largest share. The separation and purification of gases from raw natural gas, which guarantees that it satisfies the necessary quality standards prior to distribution, characterizes this segment. An essential energy source, natural gas is separated into its valuable components, such as methane, ethane, and propane, and contaminants like carbon dioxide, water vapor, and sulfur compounds are removed. For a variety of commercial, industrial, and residential uses, the safety and quality of the natural gas supply are guaranteed by these procedures.
The Segment with the highest CAGR is healthcare, as it is the vital role that gas separation technologies play in ensuring a steady supply of high-purity gases, especially nitrogen and oxygen. Moreover, these gases play a critical role in many medical applications, such as anesthesia, respiratory therapy, and device carrier gas. The global emphasis on patient care and healthcare quality, along with the ongoing development of medical treatments and infrastructure, has led to a steady increase in the demand for gas separation solutions in the healthcare sector.
The Asia-Pacific area accounted for the largest share. This was mostly caused by the swift urbanization and industrialization of nations like China and India, which raised the need for industrial gases. Furthermore, the growth of the energy sector, especially in the fields of renewable energy and natural gas processing, also played a significant role in the region's market dominance.
The Middle East and North Africa (MENA) region is anticipated to have the highest CAGR. The expansion of downstream industries like petrochemicals and rising investments in the oil and gas sector were the main drivers of this growth. Moreover, the region's rapid growth was facilitated by its emphasis on applying gas separation technologies to the processing of natural gas and increasing the productivity of gas production.
Some of the key players in Gas Separation market include Linde plc, Air Products and Chemicals, Inc, Air Liquide S.A., UOP LLC (Honeywell UOP), Parker Hannifin Corporation, AirSep Corporation, Matheson Tri-Gas, Inc., Cryotec Anlagenbau GmbH, Wartsila Corporation, Xebec Adsorption Inc., Generon IGS, PCI Gases and IGS CNG Services.
In July 2023, Linde plc (LIN) announced that it has signed two major agreements in Brazil for the supply of renewable energy. The new agreements are expected to result in an increase of more than 60% in Linde's global active renewable energy.
In June 2023, Honeywell International Inc. HON has entered into a definitive agreement to acquire heads-up-display assets of Swedish aerospace and defense company Saab Technology. The financial terms of the transaction are kept under wraps. The HUD system reduces the workload for pilots, helps them with increased situational awareness and increases flight safety.
In February 2023, Air Liquide and Sasol have signed two Power Purchase Agreements (PPA) with Total Energies and its partner Mulilo for the long-term supply of a total capacity of 260 MW of renewable power to Sasol's Secunda site, in South Africa, where Air Liquide operates the biggest oxygen production site in the world.