|
HS Code |
256010 |
| Chemical Name | N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine |
| Cas Number | 34562-31-7 |
| Molecular Formula | C13H28N2 |
| Molecular Weight | 212.38 g/mol |
| Appearance | Colorless to pale yellow liquid |
| Purity | Typically ≥98% |
| Boiling Point | 270-273°C |
| Density | 0.882 g/mL at 25°C |
| Flash Point | 125°C |
| Solubility | Insoluble in water; soluble in organic solvents |
| Refractive Index | 1.483-1.485 at 20°C |
| Storage Temperature | Store at room temperature, tightly closed container |
| Smiles | CCCCN1C(C)(C)CC(N)CC1(C)C |
As an accredited N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle labeled "N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine, 25g," with hazard symbols and tightly-sealed cap for safety. |
| Shipping | N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine should be shipped in tightly sealed containers under ambient conditions, away from moisture and incompatible substances. It is typically transported as a chemical substance, following all relevant regulations for hazardous materials. Appropriate labeling, documentation, and safety measures must be ensured during transit to prevent leaks and exposure. |
| Storage | **N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine** should be stored in a tightly closed container in a cool, dry, and well-ventilated area, away from direct sunlight, heat, and incompatible substances such as strong oxidizers and acids. Keep it at room temperature and protect from moisture. Ensure proper labeling and use appropriate secondary containment to prevent spills or leaks. |
Competitive N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine prices that fit your budget—flexible terms and customized quotes for every order.
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As a chemical producer specializing in hindered amines, we work hands-on every week with N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine, also known by its model number TAMINOBUTYL. This product sits at an interesting intersection of innovation and industrial demand, especially with its ongoing role in polymer stabilization. Watching the evolution of polymer manufacturing day-to-day, we've seen how the stability and performance needs of plastics keep rising. Producers want durable, light-stable materials that hold up outdoors and under tough processing steps. In this context, the supporting science and our own trial work have shown N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine proving itself both as a building block for further HALS (Hindered Amine Light Stabilizers) synthesis and as a key intermediate for custom additive development.
Our team started scaling up TAMINOBUTYL production a decade ago, not from guesswork, but because market data from our main customers—producers of plastics and coatings—kept pointing to new performance benchmarks. The push for weather-resistant polyolefins, tough automotive parts, long-lived construction films, and agricultural mulch films led us to focus on the HALS family. Here, the N-butyl derivative stands out from simple piperidines for being easier to integrate downstream. Having the butyl group in place directly supports flexibility in synthesis; chemists turn it into value-added stabilizers with characteristics not achievable using basic tetramethylpiperidinamine alone.
Some clients tell us their greatest headache comes from field complaints about fading, embrittlement, or crazing of polymer products under sunlight. Our own tests run over years of outdoor and weather chamber exposure back up laboratory evidence: Light-induced degradation often starts with free radical attacks at weak spots in the polymer matrix. Hindered amines—especially those like TAMINOBUTYL with optimal steric protection—intercept these radicals before significant damage happens. Plastics stabilized with derived HALS from our intermediate outlast those made with traditional UV absorbers or antioxidants, especially in harsh, high-irradiance climates.
Quality consistency is a mainstay at our facility. We have learned the hard way that even tiny shifts in impurity levels or amine values can sink downstream performance, upsetting not only formulators but brands relying on end-use durability claims. Our operators catch things early on the line, using custom inline sensors and regular GC-MS checks. This diligence evolved as our customers demanded more openness in batch records, asking for more than just the certificate of analysis—a trend pushed by brand owners caught in recalls or warranty disputes years after product shipments.
On the production side, N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine has made itself an easier molecule to handle than other bulk amines. The butyl group alters its volatility, which means less evaporation loss and more predictable mass balances in continuous synthesis. Processing staff value this trait. Storage tanks can hold charge for weeks with low risk of vapor leaks or excessive fume management, unlike lighter, short-chain piperidines. During synthesis, reaction steps remain cleaner, giving us purer output and simplifying purification.
For downstream users, the true value emerges at the formulation bench. Unlike less hindered or unsubstituted piperidines, the N-butyl version resists unwanted side reactions when blended or reacted with sensitive monomers or additives. Polymer engineers and compounding managers recognize this stability, especially when pushing for tighter product specifications around yellowing and physical integrity. With its measured amine content and low residual solvent traces, the product integrates cleanly during masterbatch production or in-situ HALS synthesis. Any deviation in supply quality is swiftly flagged by our QC team, and we provide full batch traceability.
We run competitive profiles in our R&D labs, putting not only our product but foreign and local alternatives side-by-side in real-life compounding scenarios. The differences between TAMINOBUTYL and base 2,2,6,6-tetramethylpiperidinamine become most visible under stress—both in terms of exposure and harsh compounding. Less-hindered amines or those with different substituents show higher volatility, more odor, and increased tendency to discolor during extrusion or injection molding. For operations pushing for lower health risk (in line with evolving occupational safety standards), the reduced vapor pressure from the butyl-substituted molecule significantly cuts workplace exposure.
We often meet old hands in the compounding sector who recall the days of basic UV absorbers and cheap antioxidants. Reports on premature failures in these early generations of outdoor plastics reached us both directly and through regulatory test results on end-products. Once the switch to advanced HALS systems began, using intermediates like N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine, complaints fell off fast. Withstood cycles of test and re-test across decades, this molecule has shaped the plastic product durability landscape, making an everyday impact on how lightweight structures endure sun and time.
We see a clear footprint for TAMINOBUTYL across multiple industries. In polymer stabilization, processors rely on it for producing HALS such as 770 (bis(2,2,6,6-tetramethyl-4-piperidyl)sebacate) and related derivatives. Finished formulations go into greenhouse films, injection-molded containers, and cable jacketing. Coatings manufacturers use our intermediate as a synthon, controlling the introduction of functional groups for tailor-made stabilizers that boost product warranties. The agricultural sector leans heavily on HALS to extend useful life of plastic films, protecting crops and reducing long-term material costs; most top-tier films worldwide trace back to intermediates similar to ours.
We maintain supply partnerships directly with modifier producers, never distancing ourselves from ground-level application feedback. We visit compounders, inspect their lines, and help troubleshoot not only our intermediates but also their in-situ reactions during stabilizer synthesis. This in-plant experience shaped changes to our process, including tighter color control and more efficient purification regimens. Many of our upgrades come from operators, not top management—shop floor improvements often prove just as valuable as lab-based tweaks.
End-user associations, especially in the realm of consumer goods, expect full transparency on raw material traceability. We document every batch, including key processing parameters, in support of global compliance audits—traits increasingly demanded by corporate customers aiming for green labels and extended product cycles. Our investment over recent years in backward integration—sourcing piperidine ring structures from renewable feedstocks where feasible—reflects not only regulatory pressure, but rising customer expectations around sustainable chemistry. Carbon-conscious procurement is a reality for major buyers, and we share real figures on these metrics rather than generic statements.
Chemical purity for N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine exerts an outsized influence on its suitability for high-end HALS synthesis. Regulatory trends keep raising the bar on allowable trace contaminants, especially nitrosamines and aromatic residues. We routinely test to low ppm levels, both for our own assurance and to support fileable quality dossiers for our buyers, particularly in Europe and North America. Years of batch-to-batch performance data, including detailed downstream conversion yields, feed into ongoing improvements. Customers switch to our supply precisely to solve downstream stalling, yield variability, or product odor left by lower-grade imports.
Our plant specification for TAMINOBUTYL centers around a clear, colorless-to-pale liquid, with minimized residual water and solvent, and an assay exceeding 99%. We learned early to tune reaction conditions: slow-feed reagents, real-time monitoring of exotherms, and systematic end-point checks using NMR and titration. Other producers often cut costs by skipping these steps. Feedback from major polymer additive suppliers pointed out that even a percent of unknowns curbs stabilizer reactivity and can introduce yellowing, especially in optically critical resin grades.
Pack-out processes receive as much attention as synthesis. We ship under nitrogen to avoid oxygen-induced peroxide formation, and use lined drums to eliminate leaching or contamination from container walls. Customers in Japan and the EU first flagged subtle coloration issues a decade ago. Our process response involved not only upgraded filtration, but a full review of storage and handling at each logistics node. The payoff appeared in improved downstream resin clarity, fewer customer quality complaints, and reduced write-offs for off-grade batches. In this case, small operational tweaks drove significant field results.
Our plant environment benefits from TAMINOBUTYL’s lower inhalation hazard compared to lighter amines. Exposure studies, both internal and reported in journals, confirm reduced volatility, minimizing risk to staff during blending and transfer steps. We monitor atmospheric levels across all handling points, especially since regulatory standards for amine exposure grow tighter in our target markets. Where appropriate, we retain samples from every batch, supporting both customer and regulatory trace investigations.
We put emphasis on responsible waste and effluent handling. Our in-house treatment system neutralizes spent process streams. Continuous improvement teams identify solvent recovery strategies, letting us close the loop on thousands of liters of wash solvent per month. Our drive to reduce process byproducts takes root in community feedback—neighbors and city councilors often ask for evidence of real steps, not paper policies. This pressure motivates ongoing investment and makes us more competitive with buyers prioritizing environmental compliance.
Green chemistry gets more than lip service in our halls. Over the past five years, we piloted bio-based feedstock routes and evaluated catalysts that minimize side-product generation. While challenges remain in balancing cost and reliability for commercial-scale bio-derived intermediates, sharing real progress, including hurdles and short-term setbacks, earns credibility both with local authorities and global customers relying on ethical sourcing claims.
Production of N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine faces serious sourcing pressure, with raw material markets in flux and logistics strained by geopolitics or port closures. Our procurement team stays nimble, lining up alternative suppliers and qualifying their starting materials years ahead. We audit every vendor, often visiting their plants unannounced to verify not only paperwork, but shop floor practices. This vigilance means our buyers avoid line stoppages that plague producers relying on spot or unverified sources.
Continuous technical improvement remains a fact of life on the production line. We address repeat issues in real time—ample instrumentation picks up anomalies, and team huddles find root causes daily. Scaling new synthesis steps challenges staff, but having a dedicated pilot plant means we catch problems before full-scale lines run into trouble. Our biggest asset in this work? Line operators and engineers—everyone trusted to feed back problems, no blame attached, and rewarded for solutions that stick.
The regulatory environment never stands still. REACH, TSCA, and other standards push for tighter reporting and even full life cycle accounting. We invest not just in paperwork, but substantive process validation, so every claim stands scrutiny. Third-party audits form part of the annual routine. We log parametric data, and support customer filings, especially in markets like the EU and Japan where the paperwork often takes as long as the chemistry. Tangible certification and traceable batch records matter for downstream compliance.
Technical teams working with our N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine find that little details in production translate to big differences in applied performance. Product innovation only gets as far as your weakest intermediate; there’s no shortcut. High-purity, consistent amine supply translates into smoother HALS synthesis at the customer’s plant, better color, superior physical properties, and, more importantly, fewer post-sale headaches. End consumers rarely see the intermediate, but when they buy a long-life car bumper or crystal-clear greenhouse film, the stable additive lies at the core of the material’s service life.
Discussing product advantages often draws a skeptical ear. We build trust not with broad claims, but by running service-life simulations, participating in external round-robin tests, and being open about our processes. Multiple customers, after switching from inconsistent supply, sent back glowing field results—less yellowing, fewer reprocessing calls, better pass rates on weatherometer tests. Being the manufacturer—seeing the process from reactor to drum—lets us respond quickly to specification tweaks and proactively address field complaints, creating a feedback loop few traders or third parties can match.
We maintain an open plant-door policy for customer visits and technical audits. Lab staff and line managers answer questions on everything from impurity fingerprinting to process control philosophy. This openness more than meets audit needs—it builds a culture of improvement. Input from the field, whether from a quality manager in Spain or a compounding engineer in South Korea, flows back to the plant for direct review.
We also learn from failures. Some batches never meet our spec. Every incident, root cause, and fix goes into a shared logbook, openly discussed in regular meetings. Customers trust a manufacturer who recognizes mistakes and publishes their learning as much as their successes. This habit shapes both our internal culture and our reputation for reliability.
The future for N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine depends on two things: technical requirements of next-generation plastics and the regulatory push for safer, lower-impact chemistry. We support industry collaboration efforts—joint studies, utility patent applications, and shared field-testing. Our R&D lab looks at next-generation hindered amines, using TAMINOBUTYL as a core building block but seeking even lower extractables and higher compatibility with new bioplastics.
Safety and sustainability goals now shape how fast we turn improvements into plant practice. Our leaders commit to transparency with every major customer on process changes and environmental impact. Working directly with source material producers and end users, not through intermediaries, allows us to close the loop on innovation, supplying real-world, real-time data on performance and compliance.
Manufacturing N-Butyl-2,2,6,6-Tetramethyl-Piperidinamine goes beyond chemistry formulas. Every shift in our plant, every tanker shipped, and every audit returned shapes both our product and our customer promise. The molecular details—down to impurity levels, amine strength, and residual solvent—control not just spec sheets, but the durability, color, and performance of finished plastics used around the world.
Understanding the story behind this molecule, from its impact on operator safety to its ability to anchor tomorrow’s stabilizer chemistry, helps us produce better every year. Working as the manufacturer, elbows on the line, gives the feedback and insight needed to keep ahead in a market demanding real value—not just words on a page.
