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HS Code |
860303 |
| Chemical Name | 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) |
| Cas Number | 23337-10-8 |
| Molecular Formula | C11H14N2O4 |
| Molecular Weight | 238.24 |
| Appearance | White to off-white solid |
| Melting Point | 108-110 °C |
| Solubility | Soluble in organic solvents such as ethanol, methanol, and DMSO |
| Synonyms | Pyridinedimethanol bis(methylcarbamate), PDMBC |
| Smiles | COC(=O)NCC1=CC=CC(NCC(=O)OC)=N1 |
| Inchi | InChI=1S/C11H14N2O4/c1-16-11(15)13-7-9-3-2-4-10(12-9)8-14-6-13/h2-4H,6-8H2,1H3 |
| Storage Conditions | Store in a cool, dry place, protected from light |
As an accredited 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 250 g of 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) is supplied in an amber glass bottle with a tamper-evident cap. |
| Container Loading (20′ FCL) | 20′ FCL loads 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) securely in sealed drums/IBC tanks, maximizing container volume and safety. |
| Shipping | **Shipping Description:** 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) should be shipped in tightly sealed containers, away from incompatible substances, and protected from moisture and heat. Label containers clearly with hazard information. Follow all applicable regulations for chemical transport. Use secondary containment and ensure compliance with local, state, and federal shipping requirements to ensure safe delivery. |
| Storage | 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) should be stored in a tightly sealed container, kept in a cool, dry, and well-ventilated area away from incompatible substances such as strong acids and bases. Protect from heat, direct sunlight, and moisture. Store in a chemical storage cabinet designed for organic compounds, with appropriate labeling to prevent accidental misuse or exposure. |
| Shelf Life | 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) typically has a shelf life of 2-3 years if stored in cool, dry conditions. |
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Purity 99%: 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) with purity 99% is used in pharmaceutical synthesis, where it ensures high reaction yields and product consistency. Melting point 152°C: 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) with a melting point of 152°C is used in high-temperature resin formulations, where it maintains thermal stability and prevents matrix degradation. Molecular weight 266.27 g/mol: 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) with molecular weight 266.27 g/mol is used in specialty polymer development, where it imparts precise molecular control for targeted material properties. Viscosity grade low: 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) with low viscosity grade is used in coating applications, where it enables even surface coverage and efficient film formation. Stability temperature 200°C: 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) with stability up to 200°C is used in electronic material processing, where it provides thermal endurance and reliable device fabrication. Particle size <10 μm: 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) with particle size below 10 μm is used in additive manufacturing, where it ensures uniform dispersion and smooth surface finish of printed components. Optical clarity ≥98% transmittance: 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) with optical clarity of at least 98% transmittance is used in optoelectronic device development, where it delivers high light transmission and minimal optical distortion. Solubility in ethanol >40 g/L: 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) with solubility above 40 g/L in ethanol is used in inkjet ink formulations, where it allows for concentrated solutions and consistent print quality. Hydrolytic stability 48 hours at pH 7: 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) with hydrolytic stability for 48 hours at pH 7 is used in water-based adhesive systems, where it resists premature breakdown and maintains bonding strength. Shelf life 24 months: 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) with a shelf life of 24 months is used in specialty chemical storage, where it ensures long-term usability and reduces waste. |
Competitive 2,6-Pyridinedimethanol, bis(methylcarbamate) (ester) prices that fit your budget—flexible terms and customized quotes for every order.
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At our chemical manufacturing plant, the story of 2,6-Pyridinedimethanol, bis(methylcarbamate) begins with the kind of process control that only hands-on, batch-to-batch refinement produces. We handle this compound under strict process parameters, not for the sake of ticking boxes, but because both quality and application outcomes depend on it. We’ve watched a growing demand for specialized intermediates in the pharmaceutical, agrochemical, and specialty polymer sectors. Every time our reactors run a batch of this molecule, we know it’s going to be the backbone for critical downstream chemistry.
Our model of 2,6-Pyridinedimethanol, bis(methylcarbamate) stands as the product of real-world feedback from formulation chemists and R&D teams. We crystallize and purify with the understanding that each impurity made or retained can echo through the entire process chain. Standard production gives a white to off-white solid, free-flowing and easily handled on conventional equipment. From our lab analyses, purity targets go above 98% on a dry basis, and moisture checks do not breach the low percentiles. These numbers come from repeated calibration and control, not just hopes of a consistent outcome. Packaging ranges consider routine laboratory work and bulk scale-up. We see 1kg, 5kg, and 25kg containers move out to research parks, pilot scale installations, and commercial plants.
Our batches test out with consistent melting point ranges and low trace contaminant levels, checking every time for batch repeatability before signing off on a lot. This consistency does not spring from automation alone. It comes from a culture of root-cause investigation and standard-making forged on our shop floor.
Over years in this business, we’ve seen recurring conversations with clients who need an intermediate that bridges performance gaps. 2,6-Pyridinedimethanol, bis(methylcarbamate) fits squarely into the niche for certain high-value polymer intermediates. Its molecular structure gives it a kind of versatility that lets it anchor at the interface between performance and manufacturability. Those hydroxymethyl groups on the pyridine ring, which we’ve learned to preserve with minimal side-reactions, provide reactive sites for condensation or esterification.
Formulators in technical plastics have talked to us about the structural stability it confers—especially when thermal and hydrolytic resistance come under scrutiny. We’ve filled orders tied to specialty coatings, where the reproducibility of crosslink density matters more than just passing QC checks. Our process knowledge, tuned for minimizing degradation, connects straight to what these applications demand.
Every kilogram made heads to situations where simple pyridine derivatives don’t achieve the same chemical nuance. Its use diverges sharply from the technical grade of pyridinedimethanol. The dimethanol bis(methylcarbamate) ester sidesteps volatility and unwanted side reactions, giving formulators control over downstream synthetic steps.
Chemists who turn to us want a reliable supply chain, but more than that—they want performance traits that show up in real product runs, not just paperwork. Compared to other pyridine derivatives, this carbamate ester offers lower hazard in typical lab handling, reduced background reactivity, and a physical form primed for bench to production scale transition. The key differences we see stem from its chemical backbone. The simultaneous presence of methylcarbamate groups and hydroxymethyl functionalities makes for a compound less prone to random ring modifications, an issue our customers with low-impurity requirements have faced with similar but less rigorously processed alternatives.
Some clients look for analogues with single substitutions or shorter chains, but those options often bring volatility, unpredictable side byproducts, or simply a handling headache—dusting, caking, and static are not trivial risks on a real production line. We structure our drying, milling, and packing routines to sidestep those pitfalls, because we’ve seen how small changes cascade into unexpected process failures further downstream.
We don’t treat 2,6-Pyridinedimethanol, bis(methylcarbamate) as just another catalog item. Scale-up brought its own headaches. Early batches had inconsistent yields until we learned to control the exotherm during the methylcarbamation step. It’s easy to gloss over these points in a specification sheet, but in practice, a missed temperature jump or a poorly timed quenching step meant incomplete conversion or color contamination. We re-optimized agitation, solvent ratios, and quench strategies and worked side by side with analysts to tighten release specs.
Sticking to consistent batch records through process improvement, we managed to cut lot-to-lot variability. Our operators learned the way viscosity changes signal endpoint, long before the analytics confirm conversion. These skills make up the invisible expertise that commodity resellers or brokers seldom see. When a customer calls to troubleshoot a downstream block, our technical people know the process quirks and can walk through probable failure points because we’ve seen them ourselves.
Those of us working the reactors day in and day out understand that a reliable professional relationship grows stronger with consistent delivery and honesty about what a product can and cannot do. 2,6-Pyridinedimethanol, bis(methylcarbamate) offers a kind of value that goes past the numbers on a coupon or spec sheet. Experienced manufacturers know to look beyond a certificate of analysis and ask, “What’s the process behind this consistency?”
We’ve faced questions about trace impurities and long-term storage. Because we run the plant ourselves, we address those concerns with facts—offering real data on shelf-life under varying climates, effect of trace water content on stability, and root-cause analyses following nonconformance reports. Packaging doesn’t just shield the compound from light and moisture; it’s vacuum-sealed and nitrogen-flushed, based on loss histories seen in real warehouses, not just what the supplier brochure says is ‘recommended’. Clients sometimes ask for custom pack sizes to minimize repeated opening, and we know the reasoning from our own experience of how an opened drum can swing batch analysis figures within weeks.
Our controls start at raw material intake, right through to packaging. We keep our own fleet of reactors tasked for this compound alone in a clean zone—no cross-contamination with other nitrogenous intermediates. The difference shows in trace-level analysis: chlorides, heavy metals, and residual solvents test lower than found in many generic stock products. This did not happen overnight. We swapped in higher-grade starting pyridine and upgraded our filtration stages on customer advice. As technical demands rise, especially in regulated sectors like pharma and ultraclean polymers, we adapt routines to ensure that even background levels of unwanted elements do not creep into the final bag.
While we can produce to a typical technical grade, most shipments go out as high-purity chemical for low-tolerance applications. A lot of supply chain experts talk about just-in-time delivery and optimized costs, but experience has taught us that supply consistency trumps penny savings when it comes to critical batch runs. Independent audits from buyers have scrutinized our logs, walked the reactors and packing lines, and left with those facts in hand. This transparency earns business from advanced chemists and engineers who measure more than just headline assay numbers.
We always listen when our product brings surprises—good or bad. Not long ago, a client flagged minor crystallization within the drum under unexpected storage humidity. Investigation showed that a tweak in antistatic packaging resin introduced unforeseen condensation points. Instead of shifting blame, we adjusted our resin specs, replaced affected shipments, and logged the outcome as standard practice. The learning here is simple: only by producing the product—and responding directly to user feedback—does a manufacturer solve these issues decisively.
As environmental priorities evolve, we’ve adopted solvent recycling steps and energy recovery units in our plant. Not just for compliance or image, but because years of handle on the bottom line taught us that waste costs both money and trust among our partners looking for sustainable sourcing. For instance, modifications in the work-up phase allow us to cut aqueous effluent by repurposing process water for cooling cycles, which even downstream regulators have encouraged based on performance data from our site audits.
In chemical manufacturing, traceability of feedstock underpins trust. For 2,6-Pyridinedimethanol, bis(methylcarbamate), we look back through every batch record, sometimes revisiting pyridine and methyl isocyanate suppliers for tighter controls. Not all batches of pyridine are created equal; we found that certain lots, even with identical impurity statements, behaved differently during methylation. This isn't theory—it’s a reality faced by those who do the reactions, not just those who write the catalog. Seasonality, storage profiles, and even changes in global logistics for pyridine feedstock can introduce subtle differences to the final product.
Equipment reliability at our end also becomes a variable. A minor valve leak or an inaccurately timed solvent charge has cost us yield on more than one occasion, and we treat lessons learned as ongoing calibration, not as checkboxes.
We work with clients who need customization beyond the routine. Some projects need microbatches for early-stage synthesis, others request extra dry powder for glovebox operations. Our operators take pride in carefully charging drying ovens, adjusting the cycle based on batch size so final water content remains predictably low. Analytical support goes beyond batch release; our lab often holds back retention samples for two years, enabling retrospective analysis in the rare event of end-use concerns.
Through direct collaboration, our product has become a foundation for innovations in fire-resistant plastics and molecular scaffolds for medicinal compounds. We see those wins reflected in growing re-order patterns from industries we didn't originally target.
We’ve watched supply chains strain during border slowdowns and feedstock price jumps. By holding a modest on-site buffer stock and rotating finished goods inventory, we can fulfill orders even as upstream logistics jitter. Clients appreciate transparency: we provide real-time updates, not excuses, so their timelines stay predictable.
From our own storehouse records, we know that extended storage of 2,6-Pyridinedimethanol, bis(methylcarbamate) in humid or warm conditions can slowly degrade sample quality. We advise storage at 2–8ºC, not just because books suggest so, but because real test data tracked over years proves loss of assay only accelerates above that. Customers who ignore these lessons have called asking why sample color or melt behavior shifts after months on an office shelf. It won’t do to simply cite lab recommendations; we show batch history and, if asked, dispatch technical staff to reinforce safe-handling training.
Regulatory changes have occasionally prompted process overhauls. Nobody in chemical manufacturing avoids this. We monitor compliance updates for REACH, TSCA, and local equivalents, running trial audits on our own lines to screen for new documentation or labelling requirements. The aim is to avoid disruptions by being ahead of paperwork, rather than scrambling after changes take effect. Downstream users then benefit from reduced compliance headaches, especially in regulated markets.
It’s common for researchers to approach us not just to purchase a batch, but to get our insight on reactivity and potential side-reactions. Because we produce and test our own 2,6-Pyridinedimethanol, bis(methylcarbamate), we can provide small-scale samples for method validation, impurities profiling, and process simulation. We know which side-reactions our process suppresses, and we can recommend strategies to minimize unwanted formation of byproducts in client systems, because we've seen and resolved those cases firsthand.
Clients moving from gram scale to hundreds of kilograms rely on us to scale seamlessly. Quality and characteristics must not shift unexpectedly. We back up every shipment with reference chromatograms, methods of analysis, and analyst support, so researchers and production chemists trust that their outcomes remain consistent from microbatch to ton scale.
The work of producing 2,6-Pyridinedimethanol, bis(methylcarbamate) runs deeper than the technical. Our staff train under senior operators who learned their craft through setbacks as much as successes. A valve jam, a split drum, or instruments off-calibration: these warnings cannot be covered by checklists alone. We value problem solvers who know when to halt a process, adjust a parameter, or demand a second assay, not just for compliance, but to guard our product’s downstream value.
Many discussions about quality can sound abstract. In reality, quality shows in the ease of filtration, powder flow under real plant humidity, and the way containers stack and withstand transport. We field calls from end-users, not just purchasing agents, because ultimately, the technical outcome lies in every day details overlooked in broad summary descriptions.
Our role as manufacturer—never as a distant supplier—means persistent learning. Each failed batch teaches more about risk control, each customer complaint strengthens feedback loops, and each successful order wins trust that no brochure alone secures.
The future of 2,6-Pyridinedimethanol, bis(methylcarbamate) will shift with trends in materials science, regulatory stringency, and sustainability mandates. We focus on maintaining transparent records, offering technical context for every analytical result, and adjusting our line to meet evolving performance and purity criteria. Our willingness to adapt, invest, and communicate what really happens in manufacturing—details often invisible to those outside the plant—keeps us in a position to deliver not just product, but enduring value.
As supply chains stretch globally and expectations tighten across both regulated and specialty markets, our continued investment in robust process control, feedback-driven improvement, and direct technical engagement underlines the difference between making a chemical and merely distributing it. The decades of experience gathered in our operations, the day-to-day vigilance of our team, and our willingness to confront problems honestly—these stand behind every container of 2,6-Pyridinedimethanol, bis(methylcarbamate) we produce.
