|
HS Code |
511515 |
| Cas Number | 54758-22-0 |
| Molecular Formula | C9H17ClO |
| Molar Mass | 176.69 g/mol |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | 212-215°C |
| Density | 0.922 g/cm3 at 25°C |
| Flash Point | 85°C |
| Melting Point | -40°C |
| Refractive Index | 1.420 |
| Solubility In Water | Reacts with water |
| Odor | Pungent |
| Vapor Pressure | 0.3 mmHg at 20°C |
As an accredited Isononanoyl Chloride factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Isononanoyl Chloride is packaged in a 200 kg blue HDPE drum with a secure cap and hazard labeling for safe transport. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Isononanoyl Chloride is packed in 200 kg drums, loading approximately 80 drums (16 MT) per 20′ FCL. |
| Shipping | Isononanoyl Chloride should be shipped in tightly sealed containers, protected from moisture and incompatible substances. It is classified as a hazardous material and must be transported according to relevant regulations (e.g., UN 3265, Class 8 corrosive). Proper labeling, documentation, and handling by trained personnel are essential to ensure safe transit and storage. |
| Storage | Isononanoyl Chloride should be stored in a cool, dry, and well-ventilated area, away from sources of moisture, heat, and ignition. Use tightly sealed, corrosion-resistant containers, preferably made of glass or compatible plastic. Keep away from acids, bases, and strong oxidizing agents. Ensure proper labeling and access for trained personnel only. Follow all local and national chemical storage regulations. |
| Shelf Life | Isononanoyl Chloride has a shelf life of 12 months when stored tightly sealed in a cool, dry, and well-ventilated area. |
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Purity 98%: Isononanoyl Chloride purity 98% is used in specialty chemical synthesis, where it ensures high yield of target acylation products. Low Acid Value: Isononanoyl Chloride low acid value is used in pharmaceutical intermediate production, where it promotes minimal side-reactions during process optimization. High Stability Temperature: Isononanoyl Chloride high stability temperature is used in manufacturing heat-resistant polymers, where it maintains product integrity under elevated processing conditions. Low Water Content: Isononanoyl Chloride low water content is used in moisture-sensitive reagent formulation, where it prevents hydrolysis and guarantees consistent product quality. Molecular Weight 192.7 g/mol: Isononanoyl Chloride molecular weight 192.7 g/mol is used in precise stoichiometric resin manufacturing, where it enables accurate formulation and predictable polymer linkage. Colorless Appearance: Isononanoyl Chloride colorless appearance is used in cosmetic additive synthesis, where it provides clear and aesthetically uniform finished products. High Reactivity: Isononanoyl Chloride high reactivity is used in agrochemical intermediate production, where it increases formation rates of active compounds. |
Competitive Isononanoyl Chloride prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please contact us at +8615371019725 or mail to sales7@bouling-chem.com.
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Tel: +8615371019725
Email: sales7@bouling-chem.com
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Isononanoyl chloride has found its way into many modern manufacturing sectors because of what it can actually do on the production floor. In our own operations, we've handled the material day in and day out – not just to ship it out the door, but to make sure every batch does its job in the places that count. Unlike trading firms, we start with raw inputs and guide isononanoyl chloride through every processing step under controlled, auditable conditions. This gives us a direct perspective on its behavior, purity, and consistency – all details that downstream users notice when something goes wrong or, more often, very right.
Isononanoyl chloride, colorless to pale yellow, holds a special place among acid chlorides. Chemically speaking, it carries the formula C9H17COCl. On the production line, people most recognize its sharp, pungent odor – a real reminder to treat it with the respect all acyl chlorides demand. Our model works within a specification range set for high-quality reactivity, with a typical purity minimum of 99%. Moisture content stays low – always a non-negotiable, since hydrolysis ruins a whole batch. Packing in iron drums or HDPE containers, every step, from loading to transportation, circles back to keeping unwanted side reactions at bay.
In the business of specialty chemicals, application is king. What matters is how a reagent performs when called upon, and isononanoyl chloride shows its strengths in acylation reactions, especially making isononanoyl derivatives for the pharmaceutical, agrochemical, and materials sectors. Our facility supplies the chemical primarily to formulators who need it for advanced intermediates – molecules that become the backbone of insecticides, fungicides, and sometimes even surfactants for personal care. In-house, we've witnessed how a well-controlled batch can shave hours off reaction times, reduce unwanted byproducts, and enable very precise yields.
Every chemist who has handled crude acid chlorides knows what poor purification looks and smells like. Traces of residual acids or excess thionyl chloride slip past careless processing or when old equipment allows micro-leaks. By running in-house solvent purification, gas scrubbing, and multiple QC checkpoints, we’ve cut the rate of these rejects to almost nothing. Fewer surprises in the drum translate to fewer reactor stoppages and higher batch throughput for our customers.
Real differences among acid chlorides become clear when you’ve spent years synthesizing and packaging them. Our plant produces isononanoyl chloride alongside other acyl chlorides, such as octanoyl chloride and decanoyl chloride. Chemically, these substances look related, but their behavior in acylation or condensation reactions shows sharp differences. For example, chain length affects volatility, reactivity, and, most importantly, the physical handling of each material.
Isononanoyl chloride’s branched structure, heavier than straight-chain analogs, gives it a slight edge in certain reactions. The branching reduces susceptibility to unwanted polymerization and lowers volatility, which matters for process safety and worker exposure on the shop floor. Unlike octanoyl chloride, which tends to escape more quickly and create fume issues, isononanoyl chloride stays more contained under practical reaction conditions.
Some users have tried substituting straight-chain acyl chlorides for isononanoyl chloride, but in our pilot trials, the yield often drops, or undesired side reactions increase. We’ve documented sharper selectivity in formation of esters or amides from isononanoyl chloride, which means less fiddling with purification later. Where product quality depends on molecular architecture—such as in performance coatings or certain actives—shortcuts rarely pay off.
Every batch of isononanoyl chloride demands a disciplined process and constant attention to moisture exclusion. Even small leaks or lapses during handling can mean hydrochloric acid generation—hazardous for people and hard on equipment. Our facility uses nitrogen blanketing, closed lines, and double-sealed pump systems designed after hard lessons learned in the early days, when a few leaks turned into big headaches on rainy days.
Our technical team tracks every supply run, logging pH, color, and GC-MS data before anything leaves our site. We work with local logistics partners trained to handle dangerous goods—not just paperwork, but the hoses, tools, and containment they’ll need if anything starts to go wrong during shipping. This attention makes real differences when the season turns hot and road transport faces longer runs with fluctuating warehouse conditions.
Most handlers outside the manufacturing plant never see the upstream safeguards in action. Dispatch from our site isn’t just about drum counts. It covers multiple layers of inspection and tight documentation of every handoff, both for safety and chain of custody. These are the hurdles that separate diligent manufacturing from casual reselling, and this keeps customer lines moving smoothly.
Environmental and worker safety rules grow stricter every year, but for us, these are not just boxes to check. Responsible handling of isononanoyl chloride means more than regulatory compliance. We design and continuously improve process scrubbing, waste capture, and solvent recycling. Every kilogram of volatile loss is tracked, not just as a cost, but as an indicator of process reliability.
We’ve developed solvent reclamation routines saving thousands of liters per month. By keeping an eye on all emissions—acidic, volatile, and solid—we stay ahead of both regulation and public scrutiny. Downstream manufacturers benefit because their own audits see less risk, fewer non-conformances, and lower insurance premiums.
By applying industry best practices, we often exceed local environmental standards. This long-term outlook pays off not only in reputation but in real costs—unplanned shutdowns or compliance violations cripple operations much faster than smaller process improvements. Our continual investment in containment and process control often preempts regulatory pressure by years.
Market demand for isononanoyl chloride doesn’t only follow generic growth in chemicals. Its use tracks new launches in crop protection compounds and specialty intermediates for performance polymers. Fluctuations in both feedstock prices and regulatory status mean users want steady, transparent supply backed by real-world data, not just specifications on paper.
Over the years, feedback from direct buyers—project managers, process chemists, and plant operators—has changed our approach. Some asked for variations in drum size or for more robust documentation, particularly for pharma audits. By listening to these requests, we’ve moved away from one-size-fits-all packing. Now, genuine dialogue occurs with every long-term account, making custom arrangements possible where justified.
Some of the biggest surprises in market demand trace back to new patents and research. We keep a close watch on regulatory revision, especially as countries migrate from older solvents and intermediates to more sustainable molecules. If a downstream process shifts toward “greener” ingredients, our job is to adapt—sometimes adjusting batch size or altering cleaning routines to clear out old residues and prevent cross-contamination.
From a manufacturing perspective, raw material cost tells only a fraction of the story. Years of producing isononanoyl chloride have shown that the real expense appears in rework, lost batches, or customer downtime if quality falters. One flawed batch shipped means a chain reaction of delays, too much waste, and downstream bottlenecks—costs that swamp the few cents saved from shortcutting a process.
We run multiple in-process checks each day, not because certificates demand them, but because subtle shifts in color, odor, or titration numbers signal early problems. A sharp operator can recognize the warning signs before a batch leaves the reactor. Close teamwork on the line means every handoff—from raw feed to finished drum—gets logged, checked, and signed off. Each certificate of analysis comes from real measurements, not recycled data or averages.
Customers who’ve run into issues with poorly controlled isononanoyl chloride from resellers have returned to us for stability. Their stories show that low-bid product often leads to higher overall costs—unplanned purges, extra solvent usage, runaway side reactions, and shutdowns for cleanup. Investing in the right source up front relieves a lot of pain, and we stake our reputation on batches that perform under real-world stress.
Our factory doesn’t just produce; we pilot and troubleshoot applications for real users. Lab and plant engineers collaborate on test runs when customers ask for help with formulation changes or scaling up a new process. Over time, we’ve found that isononanoyl chloride lends itself well to the synthesis of high-value intermediates previously synthesized with less efficient reagents.
For example, in pharmaceutical development, certain molecules benefit from the steric effects delivered by the isononanoic backbone. Direct feedback from process optimizations has helped us refine reaction times, reduce excess reagent, and minimize byproduct formation. Lessons learned scale up back into our own plant operations, making the process more robust and saving effort downstream for everyone in the pipeline.
With newer applications, such as specialty additives for coatings or performance polymers, our direct manufacturing experience allows us to flag potential incompatibilities before batches are made. This ability to foresee issues stems from understanding the chemistry, process equipment, and day-to-day operational realities—skills that only years on the factory floor build.
In chemical manufacturing, nobody benefits from exaggerated claims or promises the molecule can’t deliver. We anchor our approach in hard data: titration values, GC-MS traces, and lot-by-lot analysis carried out on calibrated machinery. Overpromising on attributes or application scope sets up customers for missed targets and production headaches.
We believe that understanding the core working parameters—how well the product reacts, how stable it ships, how clean it is in multistep synthesis—matters more than logo-driven marketing or buzzwords. That attitude wins trust from plant managers, researchers, and buyers who have seen trends come and go but know that well-supported documentation outlasts any ad campaign.
New users, particularly companies shifting from bench-scale to pilot-plant production, rely on our a track record to bypass common pitfalls. We encourage all partners to request batch samples, run application tests, and review certificates of analysis. Support in problem-solving stays available even after the order ships, since an unresolved technical question today can snowball into lost days or scrapped campaigns later.
No chemical supply runs on autopilot. We address technical issues as they arise, fielding advice based on first-hand troubleshooting. From process upsets such as unexpected hydrolysis rates to practical matters like container compatibility, years of direct synthesis bring deeper insight than rehashed spec sheets. More than once, we’ve designed custom dilution or neutralization procedures for customers whose downstream processing called for specific concentrations or rapid in-line quenching.
We’ve also worked with firms fine-tuning emissions to meet upcoming environmental thresholds. Recommendations about in-plant scrubber designs, leak testing strategies, or safe waste handling techniques come straight from our own on-the-ground experience, not recycled regulatory texts. When an end user asks about scaling up a new reaction or debugging a line that keeps fouling up, we aim to share a solution based on results, not theory.
Manufacturing from raw input to finished product teaches lessons that don’t reveal themselves in spreadsheets or trade publications. Our team’s long days on the processing line involve tracking minute changes in color, viscosity, or odor—details that give away issues before analytical equipment flags them. By staying involved at every stage, we offer real assurance that each drum leaving our facility stands up in the applications that matter.
We keep a close eye on upcoming changes in sector rules, feedstock pricing, or global trade patterns. Supply interruptions, surges in demand, or changing shipping routes all feed back into daily decision-making. This level of attention, based in the reality of hands-on work, distinguishes us from operations that never touch the product.
Chemical manufacturing, at its best, runs on trust built over years—not just quick sales. We prioritize communication with customers, sharing not only product data but the pitfalls we've experienced over decades. Users depend on us for quick-witted responses to audits, urgent documentation, or troubleshooting mid-production. Over time, these touchpoints draw a line between vendor and long-term partner.
Repeat customers often seek deeper insight into performance trends, new application developments, or technical support at a moment’s notice. We welcome this transparency. The feedback cycle from large and small users alike pushes us to refine our work—modifying processes, improving packaging, or testing new configurations on demand. We view this cycle as fundamental to doing business with integrity, bridging the gap between specification sheets and real-world outcomes.
The market shifts fast. Regulations and end-user needs demand constant adaptation. Research into more sustainable production runs parallel with our efforts to keep emissions low and efficiency high. Working closely with both innovators and established firms, we seek new routes to better, safer, and more sustainable isononanoyl chloride output.
We source raw materials from responsible suppliers, audit every critical process, and track all shipments from origin to destination. Downstream users know where their input has come from, how it was made, and what performance they can actually expect. Our approach, built on firsthand experience, smooths out both the technical and logistical bumps for our customers.
We’re always open to requests, pilot studies, or customized orders based on real production needs. Our practice remains to share honest feedback, supported by data and grounded in reality. As demand for specialty intermediates grows—with mounting pressure for cost, safety, and sustainability—our experience as manufacturers ensures every solution remains actionable and proven on the ground.
