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HS Code |
897230 |
| Chemicalname | Pyridine-2-carbonylchloridehydrochloride |
| Casnumber | 26449-37-0 |
| Molecularformula | C6H5Cl2NO |
| Molecularweight | 178.02 g/mol |
| Appearance | White to off-white powder |
| Meltingpoint | 128-133°C |
| Solubility | Soluble in water and polar organic solvents |
| Synonyms | 2-Pyridinecarbonyl chloride hydrochloride |
| Boilingpoint | Decomposes before boiling |
| Storageconditions | Store at 2-8°C, keep dry, tightly closed |
| Ecnumber | 247-688-5 |
As an accredited Pyridine-2-carbonylchloridehydrochloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Pyridine-2-carbonylchloridehydrochloride, 25g, is supplied in a tightly sealed amber glass bottle with tamper-evident cap and hazard labeling. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Pyridine-2-carbonylchloridehydrochloride is typically packed in 20′ containers, using sealed, UN-approved drums, ensuring safe transport. |
| Shipping | Pyridine-2-carbonylchloride hydrochloride should be shipped in tightly sealed containers, protected from moisture and light, and clearly labeled as hazardous. Transport must comply with relevant regulations for corrosive and toxic substances, using secondary containment and appropriate documentation. Handle with personal protective equipment and ensure prompt delivery to minimize risk of degradation. |
| Storage | Pyridine-2-carbonylchloride hydrochloride should be stored in a tightly sealed container, kept in a cool, dry, and well-ventilated area, away from moisture and incompatible substances such as strong bases and oxidizing agents. Protect from light and sources of ignition. It is recommended to store this chemical under an inert atmosphere, such as nitrogen or argon, to prevent degradation. |
| Shelf Life | Pyridine-2-carbonylchloride hydrochloride should be stored tightly sealed, in a cool, dry place; stable for at least 2 years under recommended conditions. |
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Purity 98%: Pyridine-2-carbonylchloridehydrochloride with purity 98% is used in pharmaceutical intermediate synthesis, where it ensures high conversion efficiency and product yield. Melting Point 178°C: Pyridine-2-carbonylchloridehydrochloride with a melting point of 178°C is used in heterocyclic compound manufacturing, where thermal stability enables reliable process control. Moisture Content <0.5%: Pyridine-2-carbonylchloridehydrochloride with moisture content less than 0.5% is used in peptide coupling reactions, where minimized hydrolysis improves reaction specificity. Particle Size <50 µm: Pyridine-2-carbonylchloridehydrochloride with a particle size less than 50 micrometers is used in fine chemical formulation, where enhanced surface area supports rapid dissolution rates. Stability at 25°C: Pyridine-2-carbonylchloridehydrochloride stable at 25°C is used in reagent storage protocols, where consistent reactivity is preserved over extended periods. Molecular Weight 194.03 g/mol: Pyridine-2-carbonylchloridehydrochloride with molecular weight 194.03 g/mol is used in analytical reference standards, where accurate mass calibration ensures precise quantification. Color Off-white: Pyridine-2-carbonylchloridehydrochloride of off-white color is used in dye precursor synthesis, where color uniformity indicates batch-to-batch consistency. Solubility in DMF: Pyridine-2-carbonylchloridehydrochloride with high solubility in DMF is used in solution-phase organic synthesis, where rapid reagent dispersion accelerates reaction kinetics. Assay ≥99%: Pyridine-2-carbonylchloridehydrochloride with assay not less than 99% is used in agrochemical intermediate production, where purity supports predictable chemical transformations. Hydrochloride salt form: Pyridine-2-carbonylchloridehydrochloride in hydrochloride salt form is used in controlled pH synthetic pathways, where enhanced solubility and stability optimize formulation processes. |
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In a facility where scale, safety, and consistency underpin every step, introducing a compound like Pyridine-2-carbonylchloridehydrochloride means talking straight about the chemistry—no bells and whistles, just grounded facts and years of hands-on work. This compound, with Model Number N2CCCH-HCl, holds its own as a specialty intermediate among the suite of pyridine derivatives we produce. Pyridine-2-carbonylchloridehydrochloride occupies a unique space in our operations, because the process of making and managing it gives us a clear sense of its character, applications, and the differences that matter next to other reagents, especially for customers who care about both chemical performance and reliability.
Our technicians work with a precise stoichiometry to chlorinate pyridine-2-carboxylic acid, raising pressure and controlling temperature within strict limits. We know the smell, the reactivity, and the chill it brings to the process line. Hydration and hydrochloride formation calls for careful timing; too much moisture, and yields dip, too little and you get dusting or crystal faults. Batch inspection checks both sterility and reactivity—this matters because even a slight deviation can change how it reacts in the next downstream synthesis. Granule size and purity range between 98% and 99.5% on our scale; every lot shows consistent particle profile, which helps avoid the kind of unexpected behavior you might see from irregular, multi-source material.
We never load a drum without GC-MS and titration records on hand. Our production lines regularly handle from 100-kilo pilot runs up to full-metric ton orders, and the scale shifts with customer demand. In our view, volume is never an excuse for shortcuts. We monitor residual moisture, detect low-level byproducts, and ensure chloride content stays tight. Real-life batch logs show that with controlled cooling and adequate agitation, we avoid sticky agglomerates—a small point with big impact on scale-up and formulation.
The main reason Pyridine-2-carbonylchloridehydrochloride sees repeat orders comes from its strong performance as an acylating agent, particularly in the pharmaceutical and agrochemical sectors. We’ve supplied it to chemists who rely on that reactive acyl chloride group to open up pyridine rings or to introduce 2-pyridylcarbonyl functionality onto other ligands. The hydrochloride salt form, stabilized during our process, lowers volatility and gives a handling advantage over free acyl chlorides. In pill coating, advanced intermediate synthesis, and crop protection chemistry, these properties matter: greater reactivity control, easier metering, and a bit more shelf stability.
Real benefits show up in reduced losses. If you’ve ever lost a reactor batch because your acyl chloride decomposed or vaporized out, you know how frustrating (and costly) that is. The powder flows in a controlled way through systems, and this cuts down on static discharges and airborne loss. Packaging is double-lined, inert-gas flushed, and sealed to limit oxygen ingress—experience has shown us that skipping extra layers always risks quality drift, especially when entering humid climates.
Our staff handle this chemical with rigorous respect for safety protocols. The hydrochloride salt isn’t as volatile or noxious as the parent acyl chloride, but still requires local ventilation and a careful eye. Minor spills release a biting odor; lab tests confirm that containment and prompt neutralization with sodium bicarbonate, followed by water rinse, handle these events reliably. Not every facility can afford purpose-built reactors or closed conveyance systems, but from our experience, investing in these pays back with less down time, lower nagging maintenance, and a boosted safety record.
End-users often want to know how to keep this compound in best shape. Controlled room temperature, low humidity, opaque containers—our warehouses stick to these with logging throughout the supply cycle. We recommend quick transfer from shipping drums to working vessels to avoid caking, which can start within a few hours in high humidity. Clients have sometimes struggled with clumped product from other suppliers, but we’ve found simple steps like inner polyethylene bags and silica gel packs make a difference in keeping it freely pourable.
Here's where working in a manufacturer’s shoes gives some perspective. Pyridine-2-carbonylchloridehydrochloride stands apart from generic acyl chlorides, such as benzoyl chloride or acetyl chloride, in ways beyond just formula. Its electron-rich pyridine system means reactivity in nucleophilic substitution is sharper—some reactions can proceed at lower temperature, with fewer side products. Many competing acyl chlorides need stronger catalysis or longer run times, and the cleanup can become laborious.
We have seen customers choose this compound over plain pyridine or other pyridinecarboxylic acid derivatives when aiming for more selective acylation or when the downstream product needs a built-in nitrogen handle. For pharma synthesis, in-house chemists often comment that its salt form, compared to the free base or acid, makes for easier purification and higher final yield. In catalyst and ligand development for fine chemical processes, the attached pyridine ring enables chelation and site-specific activation not possible with basic aromatic acyl chlorides.
Less experienced buyers sometimes ask about using alternative pyridine halides or substituting with bulkier or less selective acylating species. From our years turning out product and seeing real process feedback, these swaps can undermine both yield and throughput—impurity profiles drift, batch times stretch, and quenching waste rises. The specificity of Pyridine-2-carbonylchloridehydrochloride comes through not in a brochure promise, but in batch records, product stability over time, and repeatable customer outcomes.
Over the past decade, we have shipped this compound into projects spanning peptide coupling, crop protection agent synthesis, dye intermediates, and active pharmaceutical ingredient (API) building blocks. Some laboratories use it for selective amide formation, making beta-lactams and heterocyclic drugs. In technical grade, it goes into complexing agents and pigment synthesis, harnessing both the chlorination and pyridine features.
Bulk customers tell us they look for a clean, predictable reagent: one that doesn’t force awkward workarounds at scale. Since our facility sits close to major logistics hubs, we can minimize lag between production and delivery, reducing risk of product age and degradation. We often schedule just-in-time production for clients with stringent storage controls, so their workflows don’t suffer from sub-par or partially decomposed reactant. Cold-chain logistics and on-site inventories further support these operations; once product leaves our plant, we stay in communication through arrival, validating every shipment’s chain-of-custody.
We sometimes hear from R&D teams testing this compound for new ligation chemistry, including custom functionalization of bioactive molecules. Our pilot line turns out custom-lot size batches for these early-stage projects, and feedback loops directly into our process controls. These collaborations, where chemists can phone or visit our plant, build not just trust but better results—chemistry progresses faster when your supplier admits what works, what hasn’t, and what purity tolerances are possible.
No single batch is perfect, and we don’t claim otherwise. Contaminants do creep in, mostly at trace levels from starting material, glassware, or process water. Our labs run full-panel impurity screening using both HPLC and GC-MS, reporting findings with each batch. On rare occasions, we’ve had to quarantine product when a single outlier appeared in the spectral readout—downtime that’s costly for us, but line stoppages for downstream users are worse.
We notice over the years, the biggest limitation for our customers arises when someone substitutes a commercial grade for a pharma or electronic grade application—trace metals or halides can catalyze side reactions, yield off-spec product, or risk final product rejection. Tight documentary controls and data transparency go a long way here, because the buyer’s lab can trace any irregularity right back to original synthesis conditions. Such accountability rarely pops up in short-chain sourcing or third-party distribution.
One limitation, which comes up mostly for specialty users, involves the compound’s moisture uptake properties. Left exposed, it pulls water from the air fast, turning from powdery to sticky. Staff training, careful QA, and improved container design minimize this, but nature always pushes back. Customer trials sometimes show variation in reactivity if product sits too long between open-and-pour cycles. Our advice: order for near-term use, coordinate rapid decanting, and avoid stockpiling for months unless storage is tightly controlled.
Waste from this compound’s use requires proper handling—not just for compliance, but community safety. Our wastewater traps and incinerators follow best practices, and we urge customers to install neutral catchment and local exhaust. While bigger clients usually have these systems, smaller operations sometimes overlook evaporation risk or accidental drain discharge. Community health and local regulation shape our plant layout; close monitoring of stormwater outflows ensures we catch problems early, before they escalate.
Making Pyridine-2-carbonylchloridehydrochloride at industrial scale teaches certain hard lessons. Raw input supply disruptions, reactor fouling, changes in building air-handling—these everyday hiccups demand agile adjustment. Our supervisors spend time tweaking process windows when climate, feedstock, or customer spec shifts, ensuring nothing ships that wouldn’t pass a synthetic organic chemist’s toughest scrutiny.
Direct relationships with end-users mean our feedback loops work quicker. If a pharma lab worries about an impurity spike or an agrochemical plant flags handling issues, our teams can adjust parameters or modify packaging almost immediately. We’ve run trials reducing fine dust formation using anti-caking agents, trialed alternative drum linings for extra moisture-resistance, and participated in multi-party trouble-shooting for scale-up trials involving this compound. Documentation stays thorough and traceable, from lot formation to shipping manifest. Robust SOPs for batch control, sanitation, and waste management set our operation apart from brokers or trading desks, whose focus skews toward price and simple turnarounds.
Industry sometimes leans into generic alternatives for cost savings. We understand the pressure. Still, the volume of feedback we receive from those returning after trialing off-brand or poorly-controlled variants underlines the importance of a direct manufacturing relationship. Material origin, synthesis history, and genuine batch transparency add layers of reliability not possible by dealing with intermediaries whose processes we can’t see. For us, supplying this compound is not just about moving material, it’s about chemistry measured in both yield statistics and user trust.
Economic pressures, shifting customer requirements, and evolving regulatory standards steadily raise the bar on what’s expected from manufacturers of niche chlorinated pyridines. Price volatility in raw materials sometimes restricts scheduling flexibility and order certainty. Still, we hedge stock, diversify supply, and focus our procurement on established suppliers with audited safety records.
Quality assurance never stands still. Years ago, environmental inspectors raised the alarm on vented HCl gas escapes during batch acidification. That led us to overhaul vent scrubbers, install in-line monitoring, and revise the staff’s HAZOP response. Each improvement, born from gritty day-to-day experience, increases both staff safety and local air quality. It reinforces our role not just as a vendor but as a long-term partner to safety-conscious buyers and the wider community.
Climate variability and energy market fluctuations rarely make the headlines in specialty chemical production, but we see their marks in power supply and cooling costs. To manage product consistency, especially in high summer humidity, we back power with dedicated generators and tweak process water cooling, maintaining product granularity and shelf life. This ongoing adaptation, hands-on not theoretical, helps sustain true-to-spec products over long runs. We’ve guided customers through adjusted storage and stock levels during extended heat waves, helping minimize spoilage or delivery uncertainty.
Customers expect more than technical data sheets—they want chemistry backed by real-world results, accessible support, and no surprises in documentation, quality, or supply chain risk. We answer tough questions about raw sourcing, batch deviations, or waste management by bringing engineers and operators to the front line. This transparency, paired with experience running every unit operation, builds the confidence client projects need to move to the next step.
Producing Pyridine-2-carbonylchloridehydrochloride in bulk gives us the privilege and the challenge of supporting varied industries—from research and pilot trials to commercial-volume synthesis. By keeping open lines with users, refining process control, and holding fast to environmental stewardship, we deliver more than a compound—our reputation as a hands-on manufacturer working for, and with, each buyer.
For those who settle for basic compliance and a low upfront sticker, there’s always another option. For clients seeking not just a material but a collaborative partner in specialty chemical supply, our foundry, its people, and the track record built with each drum, continue to frame what trustworthy production looks like.
