Meet the Weak Acid Cation Exchange Resin D113 FC: field notes from the plant room

I’ve walked enough treatment lines to know what really matters: stable alkalinity removal, low acid bills, and a resin that doesn’t sulk after a tough regeneration. D113 FC, an acrylic copolymer with carboxylic acid (–COOH) groups, has quietly become the go-to in decarbonization skids, beverage polishing trains, and—surprisingly—some nickel/zinc recovery loops.

Why this resin right now

Two words: energy and compliance. Plants want less caustic/acid, fewer CO2 emissions, and audit-friendly materials. A carboxylic resin in H+ form selectively removes temporary hardness (think HCO3−, CO3^2− salts of Ca/Mg) before RO or polishing. In fact, many customers say they switched from strong acid cation (SAC) for certain duty cycles and cut acid consumption by half. Real-world mileage varies, of course.

Core spec snapshot (D113 FC)

Matrix	Acrylic copolymer, ≈8% DVB crosslinking
Functional group	Carboxylic acid (–COOH)
Ionic form (as shipped)	H+ (Na+ available on request)
Total capacity	≈4.2 eq/L (wet), real-world use may vary
Moisture content	48–56%
Particle size	0.4–1.2 mm, UC ≤ 1.6 (typ.)
Operating pH	4–10 (best capacity in slightly acidic range)
Max temp	≈120 °C (short term)
Service life	3–5 years depending on fouling/regeneration

Applications I keep seeing

• Decarbonization pre-RO: remove temporary hardness to protect membranes.
• Boiler make-up: reduce alkalinity before thermal degassing (saves steam).
• Electroplating: Zn/Ni recovery and rinse water polishing.
• Biochemical purification: gentle cation exchange for sensitive streams.
• Beverage and food plants: alkalinity trim for taste stability.

How it’s run (field-proven sequence)

1. Service: H+ form exchanges with Ca(HCO3)2/Mg(HCO3)2; alkalinity is neutralized.
2. Backwash: 50–70% bed expansion; remove fines and reclassify.
3. Regeneration: 2–4% HCl or ≈1–2% H2SO4, 1.5–2.5 BV, slow then fast rinse.
4. Rinse to conductivity target; return to service. Pressure drop kept

Testing and QA typically follow ASTM D2187 for capacity/physical integrity, with lot traceability under ISO 9001. For potable applications, engineers ask for NSF/ANSI/CAN 61 compliance—always check the latest certificate for a given batch, to be honest.

Vendor-at-a-glance

Vendor	Origin	Capacity (≈eq/L)	Lead time	Certs
LIJI D113 FC	Wei County, Xingtai, Hebei, China	≈4.2	around 2–4 weeks	ISO 9001; NSF 61 on request
Vendor A (WAC)	EU	≈4.0	3–6 weeks	ISO 9001/14001
Vendor B (WAC)	US	≈4.1	stock-dependent	NSF 61; ISO 9001

Customization & real feedback

Options I’ve seen shipped: H+ or Na+ form; tighter mesh (0.6–0.8 mm) for faster kinetics; pretreatment with SO2 scavengers for chloramine-prone water. One beverage client told me, “it just made the RO happier.” Another from an electroplating shop said recovery payback came in under 7 months.

Mini case notes

• Food & Bev (North China): alkalinity dropped from 220 to 20 mg/L as CaCO3, acid usage ≈1.9 BV per regen; RO delta-P steadied. Origin plant address was a plus for logistics: NO.2 East Jianshe Road, High-Tech Industrial Development South Zone, Wei County, Xingtai, Hebei, China.
• Plating Rinse Loop: 75–85% Ni/Zn capture with gentle acid desorb; media intact after 18 months, minimal bead fracture.

If you’re speccing a Weak Acid Cation Exchange Resin next to RO or EDI, I’d prioritize pressure-drop modeling, resin velocity at min/max temperature, and a sane regeneration profile. And yes, always keep a clean backwash—your future self will thank you.

Citations

1. IUPAC: Terminology of ion exchange, Pure Appl. Chem. 1993/1997.
2. ASTM D2187 – Standard Test Methods for Physical and Chemical Properties of Particulate Ion-Exchange Resins.
3. NSF/ANSI/CAN 61 – Drinking Water System Components – Health Effects.
4. WHO Guidelines for Drinking-water Quality, latest edition (alkalinity and hardness guidance).