Water treatment chemicals play a significant role in water pre-treatment for municipal and industrial use and the treatment of municipal and industrial wastewater for environmentally safe disposal. The growing popularity of chemical-based mobile water treatment services, installation of zero liquid discharge and minimal liquid discharge infrastructures, and the need for potable water of adequate quality will contribute to increased demand for water treatment chemicals.
However, the distribution network for water treatment chemicals faces complex challenges, including the risk of natural disasters and pandemics, regulatory changes, and market fluctuations. Any disruption caused by these events in the supply of water treatment chemicals will have significant repercussions on public health. An effective and robust supply chain of water treatment chemicals is essential for public health and environmental sustainability. This report explores the resilience of the water treatment chemicals distribution network, emphasizing the importance of adapting to potential disruptions and building a robust system capable of withstanding unexpected challenges.
This study covers various chemical types, including coagulants, flocculants, activated carbon, pH conditioners, disinfectants, and fluoridation chemicals. It assesses key strategies and best industry practices through case studies to enhance the resilience of these chemical types. Resilience in the water treatment chemicals distribution network involves proactive measures to identify risk parameters and develop mitigation strategies. It includes distribution network optimization, supplier diversification, and the adoption of digital technologies for real-time monitoring and decision-making.
The study discusses the significance of stakeholder collaboration, including chemical manufacturers and water treatment plants, in fostering resilience. Incorporating sustainable practices, such as using environmentally friendly chemicals and energy-efficient processes, is also considered an essential component of a resilient distribution network.
Why is it Increasingly Difficult to Grow?
The Strategic Imperative 8™
The Impact of the Top 3 Strategic Imperatives on the Global Water Treatment Chemicals Industry
Growth Opportunities Fuel the Growth Pipeline Engine™
Scope of Analysis
Segmentation
Why the Need for Water Treatment?
Why is Supply Chain Resilience for Water Treatment Chemicals Important?
Supply Chain Resilience—Disruptions and Water Treatment Chemical Shortages
Supply Chain Resilience—Inflation and Chemical Shortages in Selected Regions
Supply Chain Resilience—The Russo-Ukrainian War
Geographic Scope
Value Chain
Competitive Landscape and Distribution Channel
Competitive Strategy
Analysis by Region
Analysis by Region (continued)
End User Preferences
Chemicals Sourced from Chlor-alkali Industry
Chlor-alkali Industry
Chlor-alkali Industry Fluctuations
Chlor-alkali Industry Fluctuations (continued)
NaOH Supply Chain Profile
NaOH Production and Risk Parameters
NaOH Production and Risk Parameters (continued)
Case Study—Caustic Soda Alternative for pH Neutralization
Case Study—Caustic Soda Alternative for pH Neutralization (continued)
Cl2 Supply Chain Profile
Cl2 Production and Risk Parameters
Cl2 Production and Risk Parameters (continued)
Sodium Hypochlorite Supply Chain Profile
Sodium Hypochlorite Production and Risk Parameters
Sodium Hypochlorite Production and Risk Parameters
Alternatives to Cl2 and Sodium Hypochlorite
Alternative to Cl2 and Sodium Hypochlorite (continued)
Ferric Chloride Supply Chain Profile
Ferric Chloride
Ferric Chloride (continued)
Alternative Coagulants—Shifting to Renewable Resources as a Core Strategy
Developing a Flocculant From the Sludge That Drinking Water Production Generates
Sulfur and Phosphorous-based Chemicals
Sulfur Availability
Sulfuric Acid Supply Chain Profile
Sulfuric Acid Production and Risk Parameters
Sulfuric Acid Production and Risk Parameters (continued)
Sulfuric Acid Production and Risk Parameters (continued)
FSA (or H Supply Chain Profile
Phosphate Rock—A Crucial Element in FSA Production
Sulfuric Acid Production and Risk Parameters
Sulfuric Acid Production and Risk Parameters (continued)
Alum Supply Chain Profile
Alum Production and Risk Parameters
Alum Production and Risk Parameters (continued)
Plant-based Coagulants as Alternatives to Traditional Metal-based Coagulants
Alternative to Traditional Alum-based Coagulants
Organic Chemicals Vs. Oxide
PAM Production and Risk Parameters
PAM Supply Chain Profile
PAM Production and Risk Parameters
PAM Production and Risk Parameters (continued)
Companies’ Efforts to Meet Growing PAM Demand
Companies’ Efforts to Meet Growing PAM Demand (continued)
Activated Carbon Supply Chain Profile
Activated Carbon Production and Risk Parameters
Activated Carbon Production and Risk Parameters (continued)
Companies’ Efforts to Meet Growing Activated Carbon Demand
Companies’ Efforts to Meet Growing Activated Carbon Demand (continued)
Companies’ Efforts to Meet Growing Activated Carbon Demand (continued)
Oxygen Supply Chain Profile
Oxygen Production and Risk Parameters
Oxygen Production and Risk Parameters (continued)
Regional Analysis—Disinfectants
Regional Analysis—pH Adjusting Agents
Regional Analysis—Flocculating and Coagulating Agents
Regional Analysis—Activated Carbon
Regional Analysis—Fluoridation Chemicals
Digitalization
Companies Leading Digitalization
Role of Digital Transformation
Growth Opportunity 1: Partnerships to Enable Smooth Supply of Raw Materials
Growth Opportunity 1: Partnerships to Enable Smooth Supply of Raw Materials (continued)
Growth Opportunity 2: Chemical Alternatives and Technology Development for Chemical Recovery
Growth Opportunity 2: Chemical Alternatives and Technology Development for Chemical Recovery (continued)
Growth Opportunity 3: Non-chemical Alternatives
Growth Opportunity 3: Non-chemical Alternatives (continued)
Your Next Steps
Why Frost, Why Now?
List of Exhibits
Legal Disclaimer
List of Figures- Timeline of Water Treatment Chemicals Supply Challenges, Global, 2020–2023
- Caustic Soda Consumption By End Use, Global, 2022
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| Deliverable Type | Market Research |
|---|---|
| Author | Simran Tamboli |
| Industries | Chemicals and Materials |
| No Index | No |
| Is Prebook | No |
| Keyword 1 | Chemical Supply Chain Insights |
| Keyword 2 | Chemical Industry Forecast |
| Keyword 3 | Water Treatment Market Dynamics |
| List of Charts and Figures | Timeline of Water Treatment Chemicals Supply Challenges, Global, 2020–2023~ Caustic Soda Consumption By End Use, Global, 2022~ |
| Podcast | No |
| WIP Number | PF31-01-00-00-00 |
Global Water Treatment Chemicals Industry: Supply Chain Resilience
Raw Materials Innovation and Value Chain Collaboration are Prominent Strategies in Building Resilience in Water Treatment Chemicals Supply
22-Dec-2023
Global
Market Research