FREE WHITE PAPER

Heading

Date
This is some text inside of a div block.
FREE WHITE PAPER

Heading 1

Heading 2

Heading 3

Heading 4

Heading 5
Heading 6

Lorem ipsum dolor sit amet, consectetur adipiscing elit, sed do eiusmod tempor incididunt ut labore et dolore magna aliqua. Ut enim ad minim veniam, quis nostrud exercitation ullamco laboris nisi ut aliquip ex ea commodo consequat. Duis aute irure dolor in reprehenderit in voluptate velit esse cillum dolore eu fugiat nulla pariatur.

Block quote

Ordered list

  1. Item 1
  2. Item 2
  3. Item 3

Unordered list

  • Item A
  • Item B
  • Item C

Text link

Bold text

Emphasis

Superscript

Subscript

Heading 1

Heading 2

Heading 3

Heading 4

Heading 5
Heading 6

Lorem ipsum dolor sit amet, consectetur adipiscing elit, sed do eiusmod tempor incididunt ut labore et dolore magna aliqua. Ut enim ad minim veniam, quis nostrud exercitation ullamco laboris nisi ut aliquip ex ea commodo consequat. Duis aute irure dolor in reprehenderit in voluptate velit esse cillum dolore eu fugiat nulla pariatur.

Block quote

Ordered list

  1. Item 1
  2. Item 2
  3. Item 3

Unordered list

  • Item A
  • Item B
  • Item C

Text link

Bold text

Emphasis

Superscript

Subscript

Download Resource
Thank you! Your submission has been received!
Oops! Something went wrong while submitting the form.

What’s Inside Your Water Filter? A CT Scan Comparison

Edited by
Date
January 14, 2025

Water filters are our silent guardians, protecting us from a whole host of invisible contaminants. But what’s happening inside them as they work tirelessly to deliver clean water? With industrial CT scanning, we can take a detailed look at the internal structure of water filters—before and after use—to uncover how they perform, age, and ultimately safeguard our health.

In this deep dive, we’ll explore four types of water filters: pitcher filters, refrigerator water filters, reverse osmosis filters, and the LifeStraw. By getting to know their inner workings, we can see how each design contributes to its effectiveness and how they handle the wear and tear of daily use.

Pitcher Water Filters

Pitcher filters are household staples, using a blend of activated carbon and ion-exchange resin to trap impurities such as chlorine, sediment, and heavy metals like lead. When water passes through, the carbon absorbs contaminants, while the resin removes specific ions to improve taste and safety. 

A CT scan of a new pitcher filter reveals a porous, uniform core of activated carbon and resin. The material’s consistency ensures even water filtration throughout the cartridge. After use, however, the scan tells a different story. Clearly-defined flow channels are visible, suggesting that water is following the same path through the filter media each time, limiting the thoroughness of filtration. The once-pristine pores are partially blocked by accumulated sediment and impurities, and denser particles have migrated to the outer edges of the core—indicators that consistent, uniform filtration is a thing of the past for this particular filter.

Refrigerator Water Filters

Refrigerator water filters deliver clean water for drinking and ice, and we barely notice them because they are directly connected to a water line. These filters rely on dense activated carbon cores enclosed within sturdy plastic shells.

In a new refrigerator filter, CT highlights the robust, porous structure of the carbon core. This setup is ideal for trapping particles, chlorine, and even some volatile organic compounds. Over time, as the filter absorbs these impurities, the core grows noticeably denser as the filter absorbs contaminants day in and day out. Initially, the plastic casing was the densest element, but after months of use, the filtration media becomes markedly denser than the outer shell. 

Reverse Osmosis Water Filters

Reverse osmosis filters take water purification to the next level, using a semi-permeable membrane composed of tightly wound layers of synthetic material. These layers create microscopic pores that allow water molecules to pass through while blocking contaminants like salts, minerals, and chemicals. The membrane is often supported by a mesh or fabric backing and enclosed in a cylindrical housing for durability and ease of installation. Reverse osmosis systems are the go-to for ultra-clean water.

We worked with the GEAR Lab at MIT to compare new vs. used reverse osmosis elements. Our scan of a new reverse osmosis filter looks almost like a lithium-ion battery, with delicate but uniform layers surrounding a columnar core. Water has a pathway, impeded as it should be only by the membrane’s mesh pores. The filter worked 12 hours on, 12 hours off, for two months, then we scanned it again. Having purified a hard water supply high in mineral content, the filter now displays scars of its valiant efforts. Scaling deposits of minerals and organic matter visibly clog the layers, restricting water flow and reducing filtration efficiency.

LifeStraw

The LifeStraw is a portable, personal water filter designed for outdoor adventures, travel in areas with unreliable water quality, and emergency preparedness. Unlike reverse osmosis, which relies on a semi-permeable membrane to remove dissolved solids, the LifeStraw uses hollow fiber membranes with microscopic pores to physically block contaminants like bacteria, parasites, and microplastics. This ensures clean drinking water on the go, without requiring electricity or extensive setup, making it ideal for hikers, campers, and those in disaster relief situations.

A CT scan of a new LifeStraw reveals its uniform, open hollow fibers, which allow water to flow freely while trapping harmful particles along the way. Over time, and with frequent use, these fibers near the inlet begin to clog as debris accumulates, reducing both flow efficiency and the safety of the water that passes through. That makes regular cleaning a must for maintaining the performance of LifeStraw in challenging environments.

Filtration for the Future

Industrial CT offers a new level of transparency into the performance and lifespan of water filters. For consumers, it provides valuable insights into the unseen changes filters undergo, helping them make informed decisions about when to replace a filter to maintain the highest water quality. It removes the guesswork, letting us see the tangible effects of contaminants and wear over time.

For manufacturers, CT scanning unlocks critical opportunities to refine designs and materials. By understanding exactly how and where blockages form, they can create filters that are not only more efficient but also longer-lasting and better suited to the diverse needs of their customers. Whether it’s tweaking carbon density or optimizing membrane layers, these improvements translate into more reliable products.

Filters are more than just tools—they’re protectors of our health and safety. CT scanning goes beyond the surface, offering a glimpse into their often overlooked work and paving the way for smarter designs. With this technology, we’re not just looking at filters; we’re transforming how they serve us, ensuring better water quality today and clearing the way for tomorrow’s innovations.

Article
Article

What’s Inside Your Water Filter? A CT Scan Comparison

January 14, 2025
Article

What’s Inside Your Water Filter? A CT Scan Comparison

Water filters are our silent guardians, protecting us from a whole host of invisible contaminants. But what’s happening inside them as they work tirelessly to deliver clean water? With industrial CT scanning, we can take a detailed look at the internal structure of water filters—before and after use—to uncover how they perform, age, and ultimately safeguard our health.

In this deep dive, we’ll explore four types of water filters: pitcher filters, refrigerator water filters, reverse osmosis filters, and the LifeStraw. By getting to know their inner workings, we can see how each design contributes to its effectiveness and how they handle the wear and tear of daily use.

Pitcher Water Filters

Pitcher filters are household staples, using a blend of activated carbon and ion-exchange resin to trap impurities such as chlorine, sediment, and heavy metals like lead. When water passes through, the carbon absorbs contaminants, while the resin removes specific ions to improve taste and safety. 

A CT scan of a new pitcher filter reveals a porous, uniform core of activated carbon and resin. The material’s consistency ensures even water filtration throughout the cartridge. After use, however, the scan tells a different story. Clearly-defined flow channels are visible, suggesting that water is following the same path through the filter media each time, limiting the thoroughness of filtration. The once-pristine pores are partially blocked by accumulated sediment and impurities, and denser particles have migrated to the outer edges of the core—indicators that consistent, uniform filtration is a thing of the past for this particular filter.

Refrigerator Water Filters

Refrigerator water filters deliver clean water for drinking and ice, and we barely notice them because they are directly connected to a water line. These filters rely on dense activated carbon cores enclosed within sturdy plastic shells.

In a new refrigerator filter, CT highlights the robust, porous structure of the carbon core. This setup is ideal for trapping particles, chlorine, and even some volatile organic compounds. Over time, as the filter absorbs these impurities, the core grows noticeably denser as the filter absorbs contaminants day in and day out. Initially, the plastic casing was the densest element, but after months of use, the filtration media becomes markedly denser than the outer shell. 

Reverse Osmosis Water Filters

Reverse osmosis filters take water purification to the next level, using a semi-permeable membrane composed of tightly wound layers of synthetic material. These layers create microscopic pores that allow water molecules to pass through while blocking contaminants like salts, minerals, and chemicals. The membrane is often supported by a mesh or fabric backing and enclosed in a cylindrical housing for durability and ease of installation. Reverse osmosis systems are the go-to for ultra-clean water.

We worked with the GEAR Lab at MIT to compare new vs. used reverse osmosis elements. Our scan of a new reverse osmosis filter looks almost like a lithium-ion battery, with delicate but uniform layers surrounding a columnar core. Water has a pathway, impeded as it should be only by the membrane’s mesh pores. The filter worked 12 hours on, 12 hours off, for two months, then we scanned it again. Having purified a hard water supply high in mineral content, the filter now displays scars of its valiant efforts. Scaling deposits of minerals and organic matter visibly clog the layers, restricting water flow and reducing filtration efficiency.

LifeStraw

The LifeStraw is a portable, personal water filter designed for outdoor adventures, travel in areas with unreliable water quality, and emergency preparedness. Unlike reverse osmosis, which relies on a semi-permeable membrane to remove dissolved solids, the LifeStraw uses hollow fiber membranes with microscopic pores to physically block contaminants like bacteria, parasites, and microplastics. This ensures clean drinking water on the go, without requiring electricity or extensive setup, making it ideal for hikers, campers, and those in disaster relief situations.

A CT scan of a new LifeStraw reveals its uniform, open hollow fibers, which allow water to flow freely while trapping harmful particles along the way. Over time, and with frequent use, these fibers near the inlet begin to clog as debris accumulates, reducing both flow efficiency and the safety of the water that passes through. That makes regular cleaning a must for maintaining the performance of LifeStraw in challenging environments.

Filtration for the Future

Industrial CT offers a new level of transparency into the performance and lifespan of water filters. For consumers, it provides valuable insights into the unseen changes filters undergo, helping them make informed decisions about when to replace a filter to maintain the highest water quality. It removes the guesswork, letting us see the tangible effects of contaminants and wear over time.

For manufacturers, CT scanning unlocks critical opportunities to refine designs and materials. By understanding exactly how and where blockages form, they can create filters that are not only more efficient but also longer-lasting and better suited to the diverse needs of their customers. Whether it’s tweaking carbon density or optimizing membrane layers, these improvements translate into more reliable products.

Filters are more than just tools—they’re protectors of our health and safety. CT scanning goes beyond the surface, offering a glimpse into their often overlooked work and paving the way for smarter designs. With this technology, we’re not just looking at filters; we’re transforming how they serve us, ensuring better water quality today and clearing the way for tomorrow’s innovations.

Voyager Inspection Workflows
Introduction to Voyager
Introduction to Neptune
Introduction to Industrial CT
Advancing Automotive Inspection: Industrial CT for Better Outcomes
Introducing Neptune Performance and Triton Performance
Manufacturers Know Quality Costs Money. Most Don't Know How Much.
The Real Cost of a Product Recall and How to Prevent One
What Industrial CT Scanning Does for Manufacturing Quality
Next-Generation Drones: Protecting Performance with Industrial CT
Explore more posts
メインコンテンツへスキップ
New Performance scanners are here >
プラットフォーム
分野別ソリューション
すべての業界
バッテリー
医療機器
消費財
スポーツ用品
自動車
航空宇宙/防衛
農業と食品
電子機器
用途別アプリケーション
各種資料
技術資料
ケーススタディ
オンラインセミナー
Blog
Insights from lumafield
Go/No-Go
Manufacturing podcast
First Article
Editorial Publication
企業情報
会社概要
採用情報
プレスリリース
Events
Voyager を起動
お問い合わせはこちら
メニュー
製品業界
業界
すべての業界
電子機器
医療機器
自動車
消費財
バッテリー
農業と食品
航空宇宙/防衛
スポーツ用品
[アプリケーション]
リソース
リソース
ホワイトペーパー
101
オンラインセミナー
最初の記事
Go/No-Go Podcast
First Article
会社
会社
について
採用情報
プレス
Events
セールスに問い合わせる
ボイジャーを起動
© 2000 Lumafield. All Rights Reserved.
世界の”ものづくり”を変える。
分野別ソリューション
バッテリー
医療機器
消費財
スポーツ用品
自動車
航空宇宙/防衛
農業と食品
電子機器
すべての業界
用途別アプリケーション
リバースエンジニアリング
ファースト・アーティクル・インスペクション (FAI)
品質保証と品質管理
寸法測定
故障解析
材料特性評価
欠陥検出
競合ベンチマークと分析
組み立て検証
設計検証と妥当性の確認
サプライヤー適格性評価
非破壊検査 (NDT)
すべてのアプリケーション
製品
ネプチューントリトンボイジャーアトラス
各種資料
学習コンテンツメディア技術資料ウェビナーオンラインセミナー初回CTスキャン分析ガイドケーススタディCT入門エンジニアブログ
企業情報
ログイン会社概要採用情報プレスリリースブログお問い合わせ

ニュースレターに登録する

info@lumafield.com
プライバシー情報セキュリティ導入サービス契約
© 2000 ルマフィールド。全著作権所有。