Excess water in CO2 streams can lead to severe project risks, including equipment failure, blocked pipelines, and compromised system integrity. Without accurate data and a clear strategy, saturated CO2 can cause reliability issues and corrosion risks. CO2 injection projects need to consider water content in the analysis of profitability, safety, and longevity.

A comprehensive CO2 dehydration study is the key to preventing these risks. It provides the clarity you need to make informed technology decisions, ensuring your operations remain safe, reliable and efficient.

The Hidden Threat of Water in CO2 Streams

Excess water in CO2 streams poses significant risks, including:

  • Pipeline Corrosion:
    Water reacts with CO2 to form carbonic acid, which can rapidly erode infrastructure.
  • Hydrate Formation:
    Under high-pressure conditions, water can crystallize, causing blockages that disrupt operations.
  • Reduced Injection Efficiency:
    High water content undermines injection reliability, leading to expensive maintenance and unplanned downtime.

Water content targets typically range from 10 ppm to 50 lb/MMscf, depending on your transportation strategy, materials selection, and injection goals. For projects involving long pipelines or stringent injection requirements, managing water content isn’t optional—it’s essential.

Why a Dehydration Study Is Your Vital First Step

The right dehydration study transforms uncertainty into clarity. It will provide actionable insights to guide your project and give you confidence with decision-making.

Here’s how:

  1. Define Project Objectives and Constraints:
    • Document your project’s goals, specifications, and concerns. A clear starting point ensures alignment across project teams.
  2. Understand the Composition of your Gas Stream:
    • Analyze the composition of your CO2 stream, identifying contaminants that may affect dehydration technology performance.
  3. Clear Evaluation of Dehydration Technology Options:
    • Compare technologies based on CapEx, OpEx, operability, and scalability. Focus on solutions that align with your team’s expertise and long-term project needs.
  4. A Transparent and Unbiased Analysis:
    • Selecting dehydration technology often involve trade-offs between cost, efficiency, and future expandability. A comprehensive study gives you the confidence to choose the right solution without surprises.

Comparing CO2 Dehydration Technologies

Selecting the right technology depends on your project’s specific needs. A breakdown of common options is below:

  • Glycol Absorption Dehydration using Tri-Ethylene Glycol (TEG):
    • One of the most common technology suitable for many projects.
    • Requires additional modifications to achieve ultra-low water content.
    • Larger footprint and higher maintenance demands.
  • Desiccant Adsorption Systems:
    • Achieves extremely low water content, ideal for stringent requirements.
    • Higher upfront costs due to desiccant materials.
    • Ideal for projects with ultra-low water content targets.
  • Semi-Permeable Membranes:
    • Advanced systems offering high efficiency.
    • Require gas pre-treatment and higher inlet pressures, increasing upfront investment.
    • Ideal for projects needing minimal removal.
  • Chiller/Refrigeration Systems:
    • Uses dew point control to condense water from the vapor phase to a liquid.
    • Options like DEXPro leverage innovative solutions for energy-efficient cooling.
    • Effective for moderate water removal but with limitations on extreme requirements.

Real-World Success: Evaluation Findings for CO2 Dehydration

In a recent CO2 injection project, CANUSA EPC was asked to evaluate dehydration options for reducing water to a 25 lb limit in the gas stream prior to injection. 

The framework of their evaluation can be considered a minimum viable standard for dehydration analysis. If your dehydration study does not include the following considerations, it is strongly recommended to seek a more comprehensive review.

  • Reliability
  • Uptime
  • CapEx and OpEx
  • Safety
  • Schedule Risk
  • Operability/Ease of Maintenance
  • Stakeholder Support
  • Environmental Impact
  • Expansion Potential  

The following dehydration solutions were evaluated to determine which technology would best meet the client’s requirements:

  • Traditional TEG
  • Chiller Package
  • Integrated DEXPro solution.   

The result?

A detailed comparison table is available for review by downloading the full dehydration paper. A direct link is located at the bottom of this article.

In this client’s case, DEXPro stood out for its integration capabilities, environmental efficiency, and alignment with the client’s sustainability goals.

Your Next Move: Start with a Dehydration Study

Embarking on a CO2 injection project without a dehydration study is like flying blind. Start with this critical step, before assembling your project team, and you can:

  • Reduce Risks: Avoid corrosion, hydrate formation, and costly disruptions.
  • Understand Your Trade-offs: You will be faced with them. Get the data and insights you need to make confident decisions from the start.
  • Optimize Costs: Balance initial investments with long-term operational savings.
  • Achieve Scalability: Choose technologies that align with your project’s future needs.

Download the Full Paper on CO2 Injection & Dehydration:

Access the comparison of key technologies presented in this article by downloading CANUSA EPC’s paper. Click here for access: https://canusaepc.com/resources/whitepapers-e-books/

With the right knowledge and technology, you can transform challenges into opportunities and ensure your project’s success.