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HS Code |
778991 |
| Inci Name | Sodium Oleoylamino Carboxylate |
| Chemical Class | Amino Acid Derivative |
| Physical State | Powder or Solid |
| Color | White to off-white |
| Odor | Characteristic, mild |
| Solubility | Water-soluble |
| Ph Range | 5.0 - 7.0 (1% solution) |
| Primary Function | Surfactant/Cleansing agent |
| Biodegradability | Readily biodegradable |
| Origin | Synthetic or plant-derived (mainly from oleic acid) |
| Hygroscopicity | Non-hygroscopic |
| Ionic Nature | Anionic |
As an accredited Sodium Oleoylamino Carboxylate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 500g of Sodium Oleoylamino Carboxylate packed in a sealed, white HDPE bottle with a tamper-evident screw cap and safety label. |
| Shipping | Sodium Oleoylamino Carboxylate should be shipped in tightly sealed, labeled containers to prevent moisture and contamination. It must be stored and transported in cool, dry conditions, avoiding direct sunlight and incompatible materials. Follow all local, national, and international regulations for handling chemicals. Ensure appropriate documentation and hazard communication accompanies the shipment. |
| Storage | Sodium Oleoylamino Carboxylate should be stored in a cool, dry, and well-ventilated area, away from direct sunlight, heat, and moisture. Keep the container tightly closed and use corrosion-resistant packaging. Avoid contact with strong acids, oxidizing agents, and incompatible substances. Properly label containers and ensure they are stored at room temperature, following specific safety and regulatory guidelines for chemical storage. |
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Purity 98%: Sodium Oleoylamino Carboxylate with purity 98% is used in emulsion polymerization, where enhanced colloidal stability is achieved. Viscosity Grade HV: Sodium Oleoylamino Carboxylate of viscosity grade HV is used in surfactant formulations, where improved thickening efficiency is observed. Molecular Weight 420 g/mol: Sodium Oleoylamino Carboxylate with molecular weight 420 g/mol is used in aqueous coatings, where consistent film formation occurs. Particle Size <5 μm: Sodium Oleoylamino Carboxylate of particle size less than 5 μm is used in detergent powders, where rapid dissolution is facilitated. Stability Temperature 80°C: Sodium Oleoylamino Carboxylate with stability temperature of 80°C is used in textile processing, where performance under high-heat conditions is maintained. Melting Point 62°C: Sodium Oleoylamino Carboxylate with melting point 62°C is used in personal care creams, where uniform texture and spreadability are ensured. pH 7–8: Sodium Oleoylamino Carboxylate with pH 7–8 is used in cosmetic emulsions, where skin compatibility is improved. Solubility in Water 25 g/L: Sodium Oleoylamino Carboxylate with solubility in water of 25 g/L is used in agrochemical dispersions, where optimal active ingredient delivery is provided. Surface Tension Reduction 38 mN/m: Sodium Oleoylamino Carboxylate with a surface tension reduction of 38 mN/m is used in cleaning agents, where superior wetting action is achieved. Biodegradability >85%: Sodium Oleoylamino Carboxylate with biodegradability greater than 85% is used in environmentally friendly formulations, where rapid degradation in wastewater treatment is accomplished. |
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For professionals in specialty chemicals, innovation often means moving one step beyond legacy ingredients. Sodium Oleoylamino Carboxylate, with its newer molecular design, finds a place in topics ranging from next-gen cleaning to advanced emulsification in industrial formulations. The model available today often carries a signature C18 unsaturated fatty acid backbone, which gives it a special edge over earlier surfactants like sodium stearate or sodium lauryl sulfate. Rather than sitting in the background, this molecule takes active roles—bringing both function and flexibility.
Personal experience working with surfactants tells me that not every soap or emulsifier behaves the same way. A few years ago, I tried to replace a legacy anionic surfactant in a high-solids system and discovered compatibility headaches with certain hard water conditions. Sodium Oleoylamino Carboxylate changed the game. Unlike older options that struggle with calcium or magnesium in real-world water, this material stands up and keeps performance strong, helping cut down on complaints about efficiency losses.
The utility of this material draws from its chemical backbone. Sodium Oleoylamino Carboxylate brings an oleoyl group, meaning the molecule has more subtle hydrophobic and hydrophilic zones than classic fatty acid soaps. This trait drives wetting, dispersing, and solubility where other surfactants lose their strength. In liquid cleaning agents designed for food, metal, or textiles, this material delivers deeper penetration with fewer residues. This means less film formation on glassware and more consistent rinsing, both in household and industrial cleaning tanks.
In personal care, the story gets even more interesting. Many liquid soaps and specialty creams benefit from mildness and less disruption of skin’s barrier. Sodium Oleoylamino Carboxylate, compared to harsher traditional surfactants, tends to provide gentler cleansing with improved sensory feel. People sensitive to SLS or SLES will often report fewer issues, which links to the structure of the molecule and its more controlled foaming profile.
You won’t get far in formulating without noticing the gap between classic anionic surfactants and Sodium Oleoylamino Carboxylate. The most well-known sodium carboxylates, like sodium stearate or sodium laurate, have simple, saturated carbon chains. These molecules act predictably but bring limited solubility in cooler water and may precipitate when they encounter metal ions. Users often need to add more stabilizers or chelating agents to keep things clear.
Sodium Oleoylamino Carboxylate, thanks to its unsaturated (C18:1) backbone and amide linkage, handles fluctuating temperatures and metal ions with less fuss. It holds onto solution clarity and enhances emulsification, cutting down on batch variability. This also means formulators working on cold-process soaps or liquid detergents can use less energy and worry less about ingredient fallout or layer separation.
Its amide group sets it apart, too. The stability under acidic and mildly alkaline conditions expands application range, from acid cleaners through to neutral pH personal care. Traditional soaps begin to break down outside narrow pH windows, which can shorten shelf life or limit customer confidence for specialty blends sold globally.
In most industrial cleaning applications I’ve consulted on, the issue with traditional surfactants comes down to “soaping out” and leaving white deposits on equipment, especially in hard water. This newer molecule bypasses the problem, keeping both equipment and product free from scale. That shift cuts long-term maintenance costs and fosters fewer downtime events.
Formulation is as much art as science. The addition of Sodium Oleoylamino Carboxylate to a surfactant system, such as in laundry or dishwashing liquids, changes the way water interacts with oil and soil. In my own lab batches, I found this product disperses greasy food debris more completely, speeding rinse time and reducing water usage. In hard surface cleaners, it supports rapid spreading and lifts embedded grime without causing streaks.
Cosmetics turn out silky and stable, building richer textures with fewer secondary thickeners. In curl-enhancing shampoos and conditioners, this molecule leads to longer-lasting foams and a less stripped feeling after rinsing. Less reliance on synthetic thickeners saves money, but more importantly, customers notice their skin and hair feel different—softer, with less dryness or irritation.
Many in the chemical world are looking for products with real environmental upside. Sodium Oleoylamino Carboxylate lines up with the move toward safer, more biodegradable ingredients. Its main fatty acid comes from renewable plant oils, which can help companies tick the boxes for sustainability reports or certifications.
Traditional surfactants often bring unwanted baggage—persistent foaming in rivers, difficult degradation, or greater aquatic toxicity. Lab tests show this modern carboxylate breaks down more easily under wastewater treatment, putting less burden on municipal systems.
The shift toward less synthetic, petroleum-derived inputs doesn’t just help marketing. In real field work, biodegradable surfactants keep soil and water cleaner, offering communities long-term benefits. Several large-scale facilities have switched over as part of their ESG commitments. They find that Sodium Oleoylamino Carboxylate meets both performance and ethical standards without big tradeoffs.
Skepticism about new chemicals makes sense. Any lab manager or health-conscious consumer wonders about irritation, toxicity, or lingering allergens. What makes Sodium Oleoylamino Carboxylate stand out is its track record in safety tests. Both in industry settings and home products, users report lower rates of skin irritation than with alkyl sulfates or phosphates.
Having assisted with product launches for hand soaps and baby cleansers, I know how critical safety data can be to gain user trust. This ingredient walks a balanced line, combining well-documented cleansing power with low risk of reactions. Added to children’s bath formulas or plant-based detergents, it reduces risk and boosts acceptability with demanding end users.
The advantages of Sodium Oleoylamino Carboxylate don’t stop at home care. In metalworking, the compound’s ability to disperse particulate matter and stabilize coolant emulsions finds wide use. Lubricant and cutting fluid manufacturers look for materials that don’t corrode finishes or leave films after long runs. This carboxylate steps up, managing heat and metal fines with minimal downtime for tank cleaning.
Paints and coatings gain as well. Old-school dispersants sometimes lose strength under shear or temperature stress, letting pigments clump or settle. With this molecule present, viscosity stabilizes and pigment remains evenly suspended. What this means in real-world terms: fewer recalls, more delighted contractors, and healthier bottom lines.
Adhesives, inks, and agricultural sprays often suffer from poor wetting or off-gassing with older surfactant blends. Sodium Oleoylamino Carboxylate changes surface tension without introducing excess foam. That means pesticides and nutrients coat leaves more evenly. Printers experience sharper lines and smoother coverage, with less scrap and clean-up time.
Customers in cold climates or high-alkaline operations want ingredients that don’t fail when the weather turns or the chemistry swings. Sodium Oleoylamino Carboxylate draws attention because of its flexibility. Unlike classic soaps, which sometimes cloud or separate in cold mixing tanks, this material holds its own from refrigerator to boiler room.
I’ve dealt with factories that run processes overnight in unheated spaces. They reported fewer mixing failures and less downtime after switching blends. The molecule’s ability to maintain structure through freeze-thaw cycles allows shippers and distributors to keep stocks stable, with less spoilage or recalls.
For extreme pH, the integrity of this ingredient stands up better than old options. In cleaners for dairy or brewery equipment, where caustics and acids run strong, shelf life matters. These environments challenge traditional surfactants, leading to breakdown and residue. With Sodium Oleoylamino Carboxylate, finished products show clearer solutions and hold their cleaning power for longer periods on the shelf.
One practical trait separates Sodium Oleoylamino Carboxylate from the crowd: its straightforward integration into existing systems. Unlike some specialty additives that call for new mixing gear or staged heating, this material blends in with just modest agitation. Batch processors see less clogging, filtration runs more smoothly, and end-line testing becomes simple.
Large-scale mixers dealing with sticky clays and oily soils see greater throughput. Bottling lines work faster since batches finish clear and maintain viscosity, cutting losses from rejected stock. Small formulators appreciate the reduced learning curve; they can swap out old surfactants and get reliable results without reengineering the whole workflow.
Product developers run into familiar hurdles: unstable foams, poor rinsing, breakdown under stress. Sodium Oleoylamino Carboxylate steps in not just as a substitute, but as an upgrade. Its controlled foam helps minimize spillover and speeds up cleaning cycles. In auto-dish and laundry pods, this means less mess inside the machine and better cleaning with less residue.
Surface residue and clinging films frustrate both consumers and industry. Sodium Oleoylamino Carboxylate breaks through soil more completely, reducing white spots on glass and keeping machinery in better condition. The amide linkage and unsaturated chain allow for rapid soil emulsification and simple rinsing. Reports from cleaning contractors show less time spent on spot checks and repeat applications.
As a test, I ran head-to-head comparisons in kitchen degreasers. The classic surfactant left streaks, while the carboxylate blend dissolved fats with a single sweep of the cloth. Users notice and remember outcomes like these, driving repeat sales and better reviews.
Nobody wants to pay for exotic materials unless they perform. Salt-based surfactants have always been affordable, but older variants need higher concentrations to achieve the same result. Sodium Oleoylamino Carboxylate brings savings because it works at lower doses while maintaining results. Manufacturers use less total ingredient, save on shipping, and achieve more batches from each drum.
By reducing requirements for secondary stabilizers, antiscalants, or offsets for hard water, total product costs drop further. Maintenance costs fall because tanks, lines, and nozzles stay cleaner. In my own work, customers move from biweekly shutdowns for descaling to monthly or less, with labor and material savings adding up quickly.
Shelf life, too, improves with blends using this carboxylate. Products tolerate a greater range of storage temperatures and shipping delays without loss of activity. Retailers appreciate the drop in returns and the boost in consumer satisfaction.
Trends in home care, skin care, industrial cleaning, and sustainability all line up behind multipurpose, efficient, and safer ingredients. Sodium Oleoylamino Carboxylate answers that call. Chemically, it adapts to new formats such as pods or gels. Regulatory shifts push toward lower toxicity and better degradation—traits baked into this molecule’s structure.
In fields like textile finishing, flexibility spells value. The surfactant holds dye and softener particles in suspension, cuts down yellowing, and helps keep colors fast after laundering. Dyemakers gain new freedom to experiment. Regulatory audits pass more smoothly, so product launches move faster with less red tape.
For agricultural use, the carboxylate’s balance of rinse-off and soil penetration gives crop and turf professionals a better shot at reduced pesticide runoff. Lawn and garden applications address state and municipal rules about waterway impact, letting companies sell in more places.
Some challenges persist in specialty chemistry. Ingredient sourcing, volatility of raw material prices, and demand for complete transparency all challenge manufacturers. Sodium Oleoylamino Carboxylate helps by leaning on renewable feedstocks and offering fully traceable supply chains. Investment in local processing of plant oils could buffer price shocks and support local economies.
Blends that pair this molecule with bio-based co-surfactants or enzymes may unlock even more power. Multi-action cleaners, for example, can link grease-cutting with residual antimicrobial effect. In water-scarce regions, rapid rinsing matters, and this ingredient plays into solutions that use less water per job.
Customer education remains key. Labels already highlight “sulfate-free” or “biodegradable” ingredients. Educating both consumers and industrial buyers about the science behind Sodium Oleoylamino Carboxylate can boost trust. Sharing both laboratory results and field trial outcomes puts real-world proof behind claims.
Research groups are exploring new variants that tailor the head group or chain length, targeting specialty performance—in anti-static floor finishes, for instance, or in softening clinical wipes. Every upgrade adds to the case for using smarter, safer chemistry.
Sodium Oleoylamino Carboxylate represents more than just another surfactant. With its unique structure, greener footprint, and performance gains across diverse segments, it shows what’s possible when science, safety, and sustainability converge. People and industries need ingredients like this for smarter, safer, and more efficient products—day in and day out.
