|
HS Code |
605555 |
| Chemical Name | 2-Chloro-6-Trichloromethylpyridine |
| Cas Number | 1929-82-4 |
| Molecular Formula | C6H2Cl4N |
| Molecular Weight | 231.91 |
| Appearance | White to off-white crystalline solid |
| Boiling Point | 272-274 °C |
| Melting Point | 33-35 °C |
| Density | 1.53 g/cm3 |
| Solubility In Water | Slightly soluble |
| Refractive Index | 1.617 |
As an accredited 2-Chloro-6-Trichloromethylpyridine factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Amber glass bottle, 100 grams, secure screw cap, chemical-resistant label with hazard symbols, product name, CAS number, and supplier details. |
| Container Loading (20′ FCL) | 20′ FCL loads 12MT of 2-Chloro-6-Trichloromethylpyridine, packed in 25kg fiber drums, totaling 480 drums per container. |
| Shipping | 2-Chloro-6-Trichloromethylpyridine is shipped in tightly sealed containers, compliant with international hazardous materials transport regulations. It should be handled by trained personnel, labeled as a toxic and environmentally hazardous substance. Proper packaging, cushioning, and secondary containment are used to prevent leaks or spills during transit, ensuring safety and regulatory compliance. |
| Storage | 2-Chloro-6-trichloromethylpyridine should be stored in a tightly closed container, in a cool, dry, and well-ventilated area away from incompatible materials such as strong oxidizers and bases. Protect from moisture, heat, and direct sunlight. Use secondary containment to prevent leaks or spills, and ensure proper labeling. Store in accordance with local regulations and guidelines for hazardous chemicals. |
| Shelf Life | 2-Chloro-6-Trichloromethylpyridine typically has a shelf life of 2–3 years when stored tightly sealed in a cool, dry place. |
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Purity 99%: 2-Chloro-6-Trichloromethylpyridine with 99% purity is used in synthesis of agrochemical intermediates, where enhanced reaction yields and product consistency are achieved. Melting Point 70°C: 2-Chloro-6-Trichloromethylpyridine with a melting point of 70°C is used in industrial crystallization processes, where improved solid-state handling and reduced processing losses result. Stability Temperature up to 150°C: 2-Chloro-6-Trichloromethylpyridine with stability temperature up to 150°C is used in high-temperature reaction environments, where thermal degradation is minimized and product integrity is maintained. Particle Size <10 μm: 2-Chloro-6-Trichloromethylpyridine with particle size less than 10 μm is utilized in formulation of specialty coatings, where homogeneous dispersion and enhanced surface coverage are observed. Moisture Content <0.5%: 2-Chloro-6-Trichloromethylpyridine with moisture content below 0.5% is used in pharmaceutical raw material preparations, where material reactivity and shelf-life are optimized. Assay ≥98%: 2-Chloro-6-Trichloromethylpyridine with assay greater than or equal to 98% is employed in synthesis of heterocyclic compounds, where yield reproducibility and final compound purity are improved. |
Competitive 2-Chloro-6-Trichloromethylpyridine prices that fit your budget—flexible terms and customized quotes for every order.
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Working on the production line with 2-Chloro-6-Trichloromethylpyridine over the years, I’ve seen up close how this compound earned its reputation in the world of agrochemical intermediates. Reliable material with a chemical backbone built for industrial performance, it brings clarity to difficult pyrolysis pathways and helps customers achieve consistent output batch after batch without compromise. Our model, with purity ranging from 98.0% to 99.5%, goes through each stage of reaction under vigilant control, minimizing by-products and integrating smoothly into downstream syntheses.
Within the plant, this pyridine derivative enters as pale-yellow crystalline powder, free from visible contamination, offering a clear start for process engineers who care about yield stability and downstream clarity. In my experience, it often appears as the go-to intermediate, especially for those building triketone herbicides and next-generation agrochemicals. By integrating strict in-house analytical standards—high-performance liquid chromatography (HPLC) and gas chromatography (GC)—we keep the impurity profile below market averages. It gives peace of mind both to us, and to the customer on the receiving end.
This compound carves its niche in the synthesis of pyridine herbicides—specifically for active ingredients like clopyralid. It brings clean conversion, which means there’s no drifting from target product and the pathways to triclopyr and picloram stay on course. I have met formulation chemists who share the difference it makes in grubbing out wild plants as well as giving stable shelf life for their final formulation. When companies add our 2-chloro-6-trichloromethylpyridine, they mention a drop in required purification steps, shrinking downtime and avoiding “surprise” contamination during scale-up. For agrochemical developers, that translates directly to cost savings without the gamble.
On the shop floor, material handling teams recognize its stability—dry, free-flowing, packs easily, and keeps its composition stable under common warehouse conditions. Teams downstream have found less haze in their systems, fewer clogs, and reduced solvent loss. No one wants to keep stopping the line. I have watched customers using older material grades struggle with batch-to-batch variability; moving to this product took pressure off their troubleshooting teams and brought predictability into their day-to-day processing.
Every batch moves through automated systems, where melting point sits between 69 to 71°C and moisture stays below 0.3%. Dustiness is controlled through a fine mesh stage, and bags are double-sealed before release. Each order comes with a full Certificate of Analysis, not as a marketing gesture, but because our own process chemistry team depends on those numbers to tune their reactors, optimize catalysts, and keep their own performance KPIs stable. We realized fast that residual solvents like methylene chloride and toluene can ruin downstream lots, so we keep trace levels far tighter than most third-party specifications.
From my spot in the plant, I see regular audits from partners who work on regulatory-compliant pesticide synthesis. Their teams test for consistency in melting point, density, crystalline shape, and residuals, not just the main assay. Environmental monitoring teams take samples straight from the released bags to test for volatile footprints and emission profiles, giving us real-time feedback on each production cycle’s environmental load. This pushes us to keep chlorine-containing side products under 0.5%, a target that's difficult but vital for repeat customers building export-quality herbicides.
For anyone who has worked with pyridine derivatives, the temptation to settle for low-spec material can be high, especially when budgets get tight. Yet we see every day how higher purity and low-odor batches simplify every step from shipping and handling to reactor charging and final distillation. Other producers sometimes market broader-range products—assays as low as 96%—which might slide through undetected in low-stakes applications but show their true colors once a major regulatory audit or a hard-to-convert organic synthesis reveals the impurities hiding in the mix.
Our model differs from traditional benchmark grades in a few persistent ways. Product consistency keeps surprise out of critical escalations during scale-up, especially when pilot lines shift toward industrial-scale output. This means no stuck batches or unexpected polymeric residues during coupling reactions. Lower levels of matrix impurities cut risk for catalyst poisoning, a major cause of failed lots. Users in the lab notice, too: titration results line up, mass balance checks out, and throughput goes up. For a process chemist tasked with shaving weeks off their project schedule, this isn’t just about numbers—it’s a way to hit deadlines without extra cycles of purification.
Many newcomers to chemical manufacturing may not worry at first about trace contaminants until a major customer flags an issue. We've learned the hard way that green tints, mild sulfur odors, or hard-to-detect isomeric by-products leave downstream formulation teams scrambling to fix the end product—or worse, send shipments back. In our facility, we clamp down on these potential headaches through slow, carefully controlled chlorination and fully enclosed crystallization. Nothing tries our patience like having to explain to a returning client that off-color batches slipped through; that’s something we avoid through hands-on stewardship over every drum that leaves the line.
Lately, face-to-face meetings with regulatory teams feel different. Paperwork runs deeper now, and the burden of traceability falls heavily on us, as manufacturers—not just on downstream processors. Our plant team spends hours on environmental and safety audits each quarter. For a compound like 2-Chloro-6-Trichloromethylpyridine, questions about controlled substance precursors, environmental footprint, and worker exposure are part of every audit. We offer full trace documentation for each lot and work with auditors from multiple regions to make sure our material supports compliance not just at the local level but also with export partners around the globe.
Traceability sits at the core of how we organize records: every batch has a complete production history, and those details follow the product through to final customer. Years ago, a run of inferior-quality lots linked to outside suppliers produced cascading compliance issues across two continents. Bringing control and testing in-house taught us a lasting lesson and lets us offer records on raw material origins, production parameters, energy usage, and even packaging disposal. Feedback from regulatory inspectors credits us for straightforward answers and verifiable data—because a missing or vague record just creates risk up the supply chain.
Our team sits with regulators, goes through paperwork, and fields questions directly. Being asked about dioxin levels, trace metals, and cross-contamination events isn’t a surprise anymore. We build each new production cycle off lessons learned—taking in process audit reports from customers, external labs, and local authorities, then translating that feedback into fresh SOP updates. Engineers hold regular meetings just to review what failed, and why. This isn’t a luxury; it’s how we keep critical access to global agricultural and chemical markets.
The conversation never stops at the product itself. In our facility, every cycle brings a new opportunity to refine protocols and chip away at unforeseen issues. Dissolving bottlenecks at the chlorination step, upgrading filter presses to reduce waste, and automating product transfer—all of these evolved because someone on the line said, “There’s a better way.” Feedback loops with customers guide incremental tweaks in our process chemistry, logistics, and quality control. Some of the best suggestions come from a buyer who notices finer differences batch to batch—like slight shifts in flow properties or appearance in certain climates.
Sample returns and complaints become real triggers for plant adjustments rather than mere paperwork. If a customer points out a change in particle size or a faint off-color hue, our lab dives into detailed root cause analysis—tracking back to original process data, verifying all cleaning cycles, and testing warehouse stability. That open-door policy, where our technical team sits with end users and walks the shop floor together, forges the mutual trust that keeps business relationships resilient over many production cycles. No process is static, and fixing even a single persistent outlier opens fresh opportunities for refining the entire workflow.
Over the years, a steady stream of requests for ever-tighter impurity limits and packaging tweaks brought sharper focus. By switching over from traditional fiber drums to moisture-tight lined bags, we've cut caking and dusting for customers. Safer bagging lets our operators move more material each day, and shrink-wrapped pallets reduce in-plant damage and loading time. Even though these changes may only save a few minutes or a handful of rejects on a given day, the compounded benefit becomes clear across production cycles and fiscal quarters.
Safety is less about paperwork and more about relationships—teams using the material know the risks involved with poorly specified or off-ratio batches. We hear from technical directors at formulation sites who flag concerns about inhalation risks or the hazard of rogue pyrophoric impurities. By setting strict in-plant protocols for storage, handling, and loading, our teams help avoid unnecessary accidents, cleanups, or even shutdowns downstream. We take the time to explain safe handling and offer on-site training for regular buyers, believing that it’s better to invest up front than deal with emergencies or public health incidents later on.
Over the last decade, we have worked to limit workplace exposure not just for our own teams but also for those handling the chemical after it ships. Proper venting, closed-system transfers, and robust personal protective equipment lower both chronic and acute health risks. Every employee in the production area finishes the onboarding process with hands-on training in managing 2-Chloro-6-Trichloromethylpyridine, and refresher courses keep those habits sharp. The difference between a safe plant and a dangerous one often lies in the attention to routines: catching a loose valve, double-checking a seal, and monitoring airflow during drum loading. These details keep people safe and keep lines running.
While headlines may highlight chemical incidents or broad regulatory shifts, inside the factory these risks never feel abstract. They’re grounded in every valve tested, every batch sampled, and every emergency drill completed. The relationships we build with buyers, inspectors, and truck drivers turn audits and site visits into opportunities for honest feedback. Openness leads to smarter incident-prevention protocols, not just compliance for its own sake. Our responsibility as the original manufacturer gives us a unique voice in these conversations—and a clear duty to get it right every single time.
As chemical synthesis and formulation methods change, so do customer expectations. Pressure to cut environmental impact and meet new global benchmarks for purity, traceability, and safety grows each year. By integrating environmentally-conscious processes—such as solvent recovery systems, on-site effluent treatment, and process heat recycling—we cut waste and support sustainability. Customers no longer simply purchase material; they demand to know how it was made, what energy was consumed, and what the emission profile looks like.
Experience as a manufacturer shows that sustainability starts long before the final bag leaves the loading dock. We design reaction routes for maximum atom economy, optimize conversion to minimize energy and time, and audit each input for full recyclability or safe disposal. More conscientious buyers look closely at supply chain transparency, checking not just where a product comes from but how each related chemical step impacts the planet. Engineers on our team visit raw material suppliers and conduct rolling quality checks—not just for numbers on paper but also for long-term environmental compliance and social responsibility.
One trend over the past five years is the rise in small-batch, specialty formulations. Rather than just delivering container loads of commodity-grade intermediate, we’ve adapted to flexible, custom production. Short lead times, customer-specific packing, and tailored purity profiles now form a larger share of monthly output. This pull for individualized support challenges both our technical teams and logistics arms, but creates stronger partnerships with buyers, as both sides move upstream from transactional business into true technical collaboration.
Through this direct experience—not just as suppliers but as practitioners—our company supports clients navigating the regulatory landscape, product development, and efficiency goals at every level. Listening to customer requests for tighter impurity limits or suggestions for new packaging options helps us steer our own process investments and hiring priorities. By linking laboratory feedback, customer data, and process field notes, we build a real feedback loop that unlocks new improvements with each production cycle.
Manufacturing 2-Chloro-6-Trichloromethylpyridine for years has taught us that real product excellence comes from putting hands and eyes on every part of the process—from raw material sourcing and environmental safety to the way the final product lands on the warehouse shelf. Customers would rather rely on a material that’s been scrutinized by someone who knows the stakes on their side of the fence. Quality, reliability, and open dialogue remain central to our relationship with buyers around the world. Backed by hands-on experience and a strong foundation in chemistry and logistics, we commit fully to delivering a product shaped by real-world demands and evolving standards. That promise reaches from our team to yours—a partnership built on trust, technical sophistication, and the lesson that in chemical manufacturing, attention to detail is its own form of progress.
