———New Amendment]: December 2023.
Docking Personnel": [Zhou Wen].
Analysis Report on the Development Prospects and Investment Opportunities of China's Waste Acid ** Industry 2024-2031.
Chapter 1: Definition of the concept and development environment of the spent acid ** industry.
1.1 Definition of the concept of spent acid**.
1.1.1 Definition and classification of spent acid.
1) Definition of spent acid.
2) Classification of spent acid.
1.1.2 Overview of Spent Acid**.
1) The necessity of waste acid**.
2) Benefit analysis of waste acid**.
1.1.3 Classification of the national economy to which the industry belongs.
1.1.4 Illustration of the data in this report**.
1.3.1 Analysis and outlook of the domestic macro environment.
1) Analysis of GDP growth.
2) Analysis of residents' income.
3) Domestic macro environment outlook.
1.3.2 Analysis and outlook of the international macro environment.
1) Analysis of the U.S. macroeconomic environment.
2) Analysis of the macroeconomic environment in Europe.
3) Analysis of Japan's macroeconomic environment.
4) Global economic development outlook.
1.4. Analysis of the social environment of the waste acid industry.
1.4.1 The social significance of waste acid**.
1.4.2 Analysis of natural environment pollution in China.
1) Analysis of water quality and environmental pollution.
2) Air pollution.
1.4.3 Analysis of China's investment in environmental governance.
1.4.4 Analysis of the urgency of environmental governance in China.
1) The current situation of environmental risks in China.
2) Judgment of the future situation of environmental risks.
1.4.5. The impact of the social environment on the development of the industry.
1.5. Analysis of the technical environment of the waste acid industry.
1.5.1 Analysis of the current situation of waste acid ** technology in China.
1) Waste acid ** technology type.
2) Introduction to the main waste acid ** technology.
3) Advantages and disadvantages of waste acid technology.
1.5.2 Technology trend of waste acid in China.
1.5.3 The latest technology trends of China's waste acid**.
1.5.4 The impact of the technological environment on the development of the industry.
Chapter 2: Analysis of the development status of China's waste acid ** industry.
2.1 Analysis of the development history and economic benefits of China's waste acid ** industry.
2.1.1 Overview of the development of China's waste acid ** industry.
2.1.2 Development characteristics of China's waste acid ** industry.
2.2 Analysis of the current situation of market supply and demand of China's waste acid ** industry.
2.2.1 The number of waste acid enterprises in China.
2.2.2 Supply and demand of various acids in China.
1) The yield of various acids.
Chapter 3: Analysis of the competitive status and market structure of China's spent acid** industry.
3.1 Analysis of Porter's Five Forces Model in the Waste Acid Industry.
3.1.1 Competition between existing competitors.
3.1.2. Analysis of the bargaining power of key elements.
3.1.3 Analysis of consumer bargaining power.
3.1.4 Analysis of potential entrants in the industry.
3.1.5 Substitute risk analysis.
3.1.6 Summary of the competitive situation.
3.2 Analysis of investment in waste acid ** industry.
3.2.1 Investment status of waste acid ** industry.
3.2.2 Summary of investment projects in the waste acid industry.
3.3 Market structure of China's waste acid ** product segment.
Chapter 4: Panoramic preview of the industrial chain of China's waste acid ** industry and analysis of upstream equipment market development.
4.1 Panoramic preview of the industrial chain of the waste acid ** industry.
4.1.1 Panoramic preview of the industrial chain of the waste acid ** industry.
4.1.2. Analysis of the structure of waste acid emission in the industry.
Chapter 5: Analysis of the market demand potential of China's spent acid** segment.
5.1 Analysis of the development status and prospect of waste hydrochloric acid**.
5.1.1 Analysis of supply and demand of hydrochloric acid.
1) Hydrochloric acid market supply analysis.
2) Hydrochloric acid market demand analysis.
5.1.2 Analysis of waste hydrochloric acid output.
5.1.3 Waste hydrochloric acid main ** analysis.
5.1.4 Technical analysis of waste hydrochloric acid**.
1) Analysis of the current status of waste hydrochloric acid** technology.
2) Introduction to waste hydrochloric acid** technology.
3) Analysis of the development trend of waste hydrochloric acid** technology.
5.2.4 Technical analysis of waste sulfuric acid**.
1) Analysis of the current status of waste sulfuric acid ** technology.
2) Introduction to waste sulfuric acid ** technology.
3) Analysis of new technologies for waste sulfuric acid.
5.2.5 Prospect analysis of spent sulfuric acid**.
5.3 Analysis of the development status and prospect of waste nitric acid**.
5.3.1 Analysis of nitric acid supply and demand.
1) Nitric acid market supply analysis.
2) Nitric acid market demand analysis.
5.3.2 Analysis of the output of spent nitric acid.
5.3.3. The main waste nitric acid and treatment technology.
1) Photovoltaic and liquid crystal production.
2) Surface treatment of metal materials.
3) Microelectronics industry.
4) Electrode clamp and electrode foil production.
5.3.4 Prospect analysis of spent nitric acid**.
5.4 Analysis of the development status and prospect of waste phosphoric acid**.
5.4.1 Analysis of supply and demand of phosphoric acid.
1) Phosphoric acid market supply analysis.
2) Phosphoric acid market demand analysis.
5.4.2 Analysis of spent phosphoric acid output.
5.4.3 Analysis of the main ** of spent phosphoric acid.
5.4.4 Technical analysis of spent phosphoric acid**.
1) Analysis of the current situation of waste phosphoric acid ** technology.
2) Introduction to the main technology of waste phosphoric acid.
5.4.5 Prospect analysis of spent phosphoric acid**.
5.5 Analysis of the development status and prospect of fluorinated waste acid**.
5.5.1 Analysis of supply and demand of hydrofluoric acid.
1) Hydrofluoric acid market supply analysis.
2) Hydrofluoric acid market demand analysis.
5.5.2 Analysis of the output of spent hydrofluoric acid.
Chapter 6: Analysis of the current situation of waste acid production and application fields.
6.1 Titanium dioxide industry.
6.1.1 Development status and market prospect of titanium dioxide industry.
1) The development status of the titanium dioxide industry.
2) Development prospects of titanium dioxide industry.
6.1.2 Output of waste acid in titanium dioxide industry.
6.1.3 Current situation of waste acid in the field of titanium dioxide.
6.2 Non-ferrous metal industry.
6.2.1. Development status and market prospect of non-ferrous metal industry.
6.3.3 Current situation of waste acid in the iron and steel field.
6.4 Fuel industry.
6.4.1. The development status and market prospects of the fuel industry.
1) The development status and market prospect of the petroleum industry.
2) The development status and market prospect of the natural gas industry.
3) The development status and market trend of the gasoline industry.
6.4.2 Waste acid output in the fuel industry.
6.4.3 Current status of waste acid in the fuel industry**.
6.5 Acid industry.
6.5.1. The development status and market prospect of the acid industry.
1) Sulfuric acid production distribution.
2) Sulfuric acid ** analysis.
3) Prospect analysis of sulfuric acid industry.
6.5.2. Output of waste acid in the acid industry.
6.5.3 Current situation of waste acid in the field of acid production.
6.6 Lead-acid battery industry.
6.6.1. Development status and market prospect of lead-acid battery industry.
1) Lead-acid battery yield analysis.
2) Analysis of lead-acid battery sales volume.
3) Lead-acid battery industry prospects**.
6.6.2 Output of waste acid in lead-acid battery industry.
6.6.3 Current situation of waste acid in the field of lead-acid batteries.
6.7 Nitrification industry.
6.7.1 Development status and market prospect of nitrification industry.
1) Overall production of industrial explosives.
2) Industrial explosives product structure.
3) Prospect analysis of the industrial explosives industry.
6.7.2 Output of waste acid in the nitrification industry.
6.7.3 Current status of waste acid in the field of nitrification.
Chapter 7: Case study of representative enterprises in China's waste acid chain.
7.1 Comparison of the development of representatives of China's waste acid chain enterprises.
7.2 Case study of representative enterprises in China's waste acid chain.
7.2.1 Harbin Boao Environmental Technology***
1) Enterprise development history and basic information.
2) Introduction to the business status of the enterprise.
3) Enterprise business structure and sales network.
4) The business layout of the company's waste acid.
5) Analysis of the advantages and disadvantages of enterprise development of waste acid ** business.
4) The business layout of the company's waste acid.
5) Analysis of the advantages and disadvantages of enterprise development of waste acid ** business.
7.2.4 Nantong Jiuxin graphite technology development***
1) Enterprise development history and basic information.
2) Introduction to the business status of the enterprise.
3) Enterprise business structure and sales network.
4) The business layout of the company's waste acid.
5) Analysis of the advantages and disadvantages of enterprise development of waste acid ** business.
7.2.5 Liaoyang Huanya Waste Acid Regeneration Technology***
1) Enterprise development history and basic information.
2) Introduction to the business status of the enterprise.
3) Enterprise business structure and sales network.
4) The business layout of the company's waste acid.
5) Analysis of the advantages and disadvantages of enterprise development of waste acid ** business.
7.2.6 Tai'an Yongda Environmental Protection Technology ***
1) Enterprise development history and basic information.
2) Introduction to the business status of the enterprise.
7.2.8 Jiangsu Haipu Functional Materials***
1) Enterprise development history and basic information.
2) Introduction to the business status of the enterprise.
3) Enterprise business structure and sales network.
4) The business layout of the company's waste acid.
5) Analysis of the advantages and disadvantages of enterprise development of waste acid ** business.
7.2.9 Dongguan Ruide Environmental Protection Technology***
1) Enterprise development history and basic information.
2) Introduction to the business status of the enterprise.
3) Enterprise business structure and sales network.
4) The business layout of the company's waste acid.
5) Analysis of the advantages and disadvantages of enterprise development of waste acid ** business.
Chapter 8: Investment Prospects and Recommendations for China's Spent Acid Industry.
8.1 Analysis of the investment potential of China's waste acid industry.
8.1.1 Analysis of industry investment promotion factors.
1) Favorable policies.
2) Technology-driven.
3) Increase investment in environmental protection.
8.1.2 Analysis of industry investment constraints.
1) The mechanism of waste acid ** is not perfect.
2) The resource treatment of waste acid has not been promoted on a large scale.
3) Weak industry infrastructure.
8.1.3. Comprehensive judgment of the investment potential of the industry.
8.2 Waste acid**Development prospect**.
8.2.1 Industry market capacity**.
2) Market risk.
3) Macroeconomic risks.
4) Other risks.
8.4 Waste acid** investment opportunity analysis.
8.4.1 Regional Investment Opportunities.
8.4.2 Technology investment opportunities.
1) Thermochemical regeneration.
2) Bipolar membrane method.
3) Novel complexation precipitation method.
8.4.3 Segment Investment Opportunities.
8.5 Spent acid** investment strategy and sustainable development advice.
8.5.1 Industry investment strategy analysis.
1) Set up a processing station.
2) On-site service.
3) Long-term operation.
4) Control quality.
8.5.2 Investment advice for potential entrants.
1) Clear classification and standardized standards.
2) Unified deployment and hierarchical management.
3) Pay attention to the effect and promote steadily.
8.5.3 Industry sustainability recommendations.
1) Strengthen supervision at the source.
2) Improve the standard of waste acid products.
3) Establish a centralized processing center.
4) Increase policy support.
5) Strengthen scientific and technological research.
Chapter 9: Shandong Province Spent Acid** Market Analysis.
Figure 1: Main classifications of spent acid.
Figure 2: The position of the spent acid** industry in the industrial classification of the national economy.
Exhibit 3: Illustration of the report data**.
Exhibit 4: Current implementation standards related to the spent acid ** industry.
Exhibit 5: Spent acid** industry related to the upcoming implementation of the implementation of the specification standard.
Exhibit 6: Policies related to the spent acid** industry.
Figure 7: China's GDP growth trend from 2015 to 2023 (unit: trillion yuan, %)
Figure 8: China's domestic per capita income and its growth rate from 2018 to 2023 (unit: yuan, %)
Chart 9: Growth in key economic indicators in 2023** (in %)
Chart 10: Three possibilities for the impact of the pandemic on China's economy (2020 GDP growth) (in %)
Figure 11: Trends in U.S. gross domestic product (USD billions, %) from 2013 to 2023
Chart 12: US ISM Manufacturing PMI Index (unit: %) from 2018 to 2023
Figure 13: Trend of total GDP in the euro area from 2013 to 2023 (in trillions, %)
Chart 14: Eurozone unemployment rate change from 2018 to 2023 (in %)
Figure 25: Internal structure of an ion exchange resin.
Figure 26: Diffusion and exchange processes of ions.
Figure 27: Synthesis process of polyaluminium chloride.
Figure 28: Comparison of advantages and disadvantages of spent acid** technology.
Figure 29: Development characteristics of China's waste acid ** industry.
Figure 30: Regional distribution of the number of spent acid**-related enterprises in China as of 2023 (unit: households).
Figure 31: Regional distribution of the number of spent acid**-related enterprises in China as of 2023.
Figure 32: Production of sulfuric acid, hydrochloric acid, nitric acid, phosphoric acid, and hydrofluoric acid from 2017 to 2023 (unit: 10,000 tons).
Figure 33: Production, import and export volume and apparent consumption of sulfuric acid, hydrochloric acid, nitric acid, phosphoric acid and hydrofluoric acid from 2017 to 2023 (unit: 10,000 tons).
Figure 34: China's total waste acid production from 2017 to 2023 (unit: 10,000 tons, %)
Exhibit 35: Analysis of China's spent acid production** in 2023 (unit: %)
Exhibit 36: China's major waste acid producers.
Figure 37: 2017-2023 China's waste acid** volume (unit: 10,000 tons, %)
Figure 38: Market size of China's waste acid recovery industry from 2017 to 2023 (unit: 100 million yuan).
Figure 39: Example of China's waste acid plant** (unit: 10,000 yuan).
Figure 40: Pain points in the development of China's waste acid industry.
Exhibit 41: Competitive analysis of incumbents in the spent acid** industry.
Exhibit 42: Analysis of upstream bargaining power of the spent acid** industry.
Exhibit 43: Analysis of the downstream bargaining power of the spent acid** industry.
Exhibit 44: Spent Acid** Industry Potential Entrant Threat Analysis Table.
Exhibit 45: Comprehensive analysis of the five forces competition in China's waste acid industry.
Figure 46: 2019-2023 China waste acid ** industry project bidding.
Exhibit 47: Product structure of China's spent acid** segment in 2023 (unit: %)
Exhibit 48: Competitive landscape of China's spent acid** companies.
Figure 49: Distribution of registered capital of China's waste acid ** enterprises (unit: households, %)
Figure 51: Schematic diagram of the industrial chain of the waste acid industry.
Figure 52: Brief analysis of waste acid production by industry.
Figure 53: 2017-2023 China's waste acid ** equipment demand market size (unit: 100 million yuan, %)
Figure 54: Spent acid** processes involve spent acid** equipment.
Figure 55: Trends in the development of spent acid** equipment.
Figure 56: 2023-2031 China's waste acid ** equipment demand market size ** (unit: 100 million yuan).
Figure 57: China's hydrochloric acid (** content 31%) production (unit: 10,000 tons) from 2013 to 2023
Figure 58: Apparent consumption of hydrochloric acid (** content 31%) in China from 2016 to 2023 (unit: 10,000 tons).
Figure 59: China's waste hydrochloric acid output from 2017 to 2023 (unit: 10,000 tons).
Figure 60: Flow diagram of hydrochloric acid regeneration process by fluidized bed method.
Figure 71: China's spent phosphoric acid output from 2017 to 2023 (unit: 10,000 tons).
Figure 72: China's hydrofluoric acid production from 2016 to 2023 (unit: 10,000 tons).
Figure 73: Apparent consumption of hydrofluoric acid in China from 2016 to 2023 (unit: 10,000 tons).
Figure 74: China's waste hydrofluoric acid output from 2014 to 2023 (unit: 10,000 tons).
Figure 75: Fluorinated waste acids** and their composition.
Figure 76: China's titanium dioxide production from 2015 to 2023 (unit: 10,000 tons, %)
Figure 77: China's titanium dioxide product output structure in 2023 (unit: 10,000 tons, %)
Figure 78: Regional distribution of China's titanium dioxide production in 2023 (unit: %)
Figure 79: China's titanium dioxide production** (unit: 10,000 tons) from 2023 to 2031
Figure 80: Waste acid output of China's titanium dioxide industry from 2017 to 2023 (unit: 10,000 tons, %)
Figure 81: Titanium dioxide industry's waste acid ** process and application status.
Chart 82: China's output of ten non-ferrous metals from 2014 to 2023 (unit: 10,000 tons, %)
Figure 83: China's output structure of 10 non-ferrous metals in 2023 (unit: 10,000 tons, %)
Figure 84: China's production of 10 non-ferrous metals** (unit: 10,000 tons) from 2023 to 2031
Figure 85: Output of waste acid in China's non-ferrous metals industry from 2017 to 2023 (unit: 10,000 tons, %)
Figure 86: China's steel, pig iron and crude steel production from 2014 to 2023 (unit: 100 million tons).
Figure 87: Changes in the year-on-year growth rate of China's steel, pig iron and crude steel output from 2014 to 2023 (unit: %)
Exhibit 88: Production of major products in the steel industry** (unit: 100 million tons) from 2023 to 2031
Figure 89: Apparent steel consumption in China from 2014 to 2023 (unit: 100 million tons, %)
Figure 90: China's demand for steel from 2023 to 2031** (unit: 100 million tons).
Figure 91: 2017-2023 China's iron and steel industry waste acid production and growth rate (unit: 10,000 tons, %)
Figure 92: China's ** production and growth rate from 2015 to 2023 (unit: 100 million tons, %)
Figure 93: China's apparent oil consumption and growth rate from 2015 to 2023 (unit: 100 million tons, %)
Exhibit 94: International** influencing factors in 2023.
Figure 95: China's natural gas production and growth rate from 2015 to 2023 (unit: 100 million cubic meters, %)
Figure 96: China's natural gas consumption and growth rate from 2015 to 2023 (unit: 100 million cubic meters, %)
Figure 97: China's gasoline production and growth rate from 2016 to 2023 (unit: 10,000 tons, %)
Figure 98: Annual apparent gasoline consumption growth trend in China from 2016 to 2023 (unit: 100 million tons, %)
Figure 99: 2017-2023 China's fuel industry waste acid production and growth rate (unit: 10,000 tons, %)
Figure 100: Provinces with a national sulfuric acid output of more than 1 million tons in 2023 (unit: 10,000 tons).
Figure 110: 2017-2023 China's nitrification industry waste acid production and growth rate (unit: 10,000 tons, %)
Exhibit 111: Business comparison of key enterprises in China's waste acid**.
Exhibit 112: Harbin Boao Environmental Technology*** Basic Information Table.
Chart 113: 2018-2023 Harbin Boao Environmental Technology (unit: 10,000 yuan).
Exhibit 114: Business structure of Harbin Boao Environmental Technology***.
Exhibit 115: Harbin Boao Environmental Technology*** Waste Acid Business Profile.