|
HS Code |
489833 |
| Chemical Name | 4-Chloro-2-Methyl-N-Acetoacet Anilide |
| Cas Number | 24353-92-6 |
| Molecular Formula | C11H12ClNO2 |
| Molecular Weight | 225.68 g/mol |
| Appearance | White to off-white crystalline solid |
| Melting Point | 90-94°C |
| Boiling Point | No data available |
| Solubility | Soluble in organic solvents such as ethanol and acetone |
| Purity | Typically >98% |
| Storage Condition | Store in a cool, dry place; keep container tightly closed |
| Synonyms | 4-Chloro-2-methylacetoacetanilide |
| Density | Approx. 1.23 g/cm³ |
| Refractive Index | No data available |
| Flash Point | No data available |
| Usage | Intermediate for pharmaceuticals and agrochemicals |
As an accredited 4-Chloro-2-Methyl-N-Acetoacet Anilide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A white, tightly sealed 500g HDPE bottle labeled "4-Chloro-2-Methyl-N-Acetoacet Anilide" with hazard and handling instructions. |
| Container Loading (20′ FCL) | 20′ FCL contains 12 MT (metric tons) of 4-Chloro-2-Methyl-N-Acetoacet Anilide, packed in 25 kg fiber drums. |
| Shipping | `4-Chloro-2-Methyl-N-Acetoacet Anilide` is shipped in tightly sealed containers, protected from moisture and direct sunlight. The package is labeled according to hazardous material regulations. It is transported at ambient temperature, with documentation for safe handling and emergency procedures, ensuring compliance with chemical shipping standards. |
| Storage | 4-Chloro-2-Methyl-N-Acetoacet Anilide should be stored in a cool, dry, and well-ventilated place, away from direct sunlight and incompatible substances such as strong oxidizers. Keep the container tightly closed and clearly labeled. Protect from moisture and sources of ignition. Use appropriate personal protective equipment when handling and ensure good laboratory practices are followed to prevent contamination or accidental exposure. |
| Shelf Life | **4-Chloro-2-Methyl-N-Acetoacet Anilide** has a shelf life of 2–3 years when stored in a cool, dry, and dark place. |
Competitive 4-Chloro-2-Methyl-N-Acetoacet Anilide prices that fit your budget—flexible terms and customized quotes for every order.
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Years of working with specialty chemicals teach lessons that textbooks overlook. Every batch of 4-Chloro-2-Methyl-N-Acetoacet Anilide tells its story. From raw input to final inspection, the process rewards careful attention. Technical details matter, yet experience with material behavior during synthesis and purification pushes us beyond formulas on a spec sheet. Producing this compound involves more than filling a vessel and waiting on numbers; it’s about understanding reaction nuances, recognizing subtle hints at each step, and understanding the benefit precise handling brings to quality, performance, and downstream use.
You find this compound referenced in agricultural chemistry circles and among manufacturers focused on advanced intermediates. Known commonly as a key intermediate in certain crop protection agents, its reputation has grown thanks to consistent results in both laboratory and large-scale settings. Chemists value its structural features—a carefully substituted anilide ring paired with a reactive acetoacetyl group. This molecular structure unlocks reactivity for further derivatization, especially where specificity and reproducibility define the chain of production in fields like agrochemicals and pharmaceuticals.
Our operations use a robust manufacturing route established for reliability and safety. Over the years, we have iterated on solvent selection, temperature profiles, and subtle adjustments in reagent ratios. For every ton shipped, we remember the dozens of parameter tweaks made along the way. We monitor our product closely for purity, maintaining a minimum standard above 98%. Moisture and ash control requires equal vigilance, ensuring that product behavior in subsequent syntheses does not wander from expectations. Product color remains bright, and particulate profile stays fine and dust-free—a reflection of careful filtration and drying, not just an afterthought in quality control.
Handling 4-Chloro-2-Methyl-N-Acetoacet Anilide firsthand gives a sense of its functional differences compared to other substituted anilides. The presence of both methyl and chloro groups on the aromatic core changes its reactivity—most users discover increased selectivity and altered solubilization in downstream processes. The material resists hydrolysis well, outperforming some unsymmetrical analogues when exposed to ambient humidity during storage or blending. That property serves buyers who value shelf-life and processing latitude.
Customer feedback over the years paints a clear trend: consistency counts. Blends made with our product scatter less in terms of purity and composition. End-users report fewer “off spec” incidents in their finished products. Our technical support team, after troubleshooting dozens of formulations with customers, has seen how tighter lot control from the manufacturing floor shortens setup time and reduces costly downtime during scale-up.
The markets we serve notice differences measured in hours, not just fractions of a percent in purity. Crop science clients insist that batch-to-batch reliability outruns yet another decimal point. Mixing technicians remember powders that flow as promised; they do not forget dust that clogs equipment or hard caking. In response, our team works shifts during monsoon season and in winter’s humidity swings to prevent clumping and maintain pourability at the finish. The result? Fewer production stoppages, lower labor costs, and higher throughput in our customers’ plants.
Some companies look for lower-cost replacements using related compounds. From our perspective, not all anilides respond equally to process changes. We watch side reactions during synthesis with alternate chlorination patterns; yields drop or side-product profiles shift. Operators complain when substitutes introduce more volatile impurities, causing odor or color shifts in subsequent formulations. Lists of “globally acceptable” or “technical grade” variants can look similar on paper, but careful chromatographic analysis unfurls significant out-of-spec components.
Formulators targeting advanced herbicide actives come back to 4-Chloro-2-Methyl-N-Acetoacet Anilide because of its established reactivity. Off-pathway contaminants from similar compounds require additional clean-up in downstream steps—a direct drain on time, energy, and solvent. We’ve measured higher recovery rates and more stable process windows versus competing molecules, supported by decades of side-by-side trials in the field and lab.
Bulk users appreciate strengths that testimonials rarely capture. Storage stability over six months in a humid warehouse counts more than an extra half-point in certificate purity. Drum after drum gets opened and resealed; the product’s free-flowing nature and lack of caking save countless man-hours in reprocessing and cleaning. Bulk density remains steady within a tight margin, saving on material transfer and bin design headaches during continuous processing. Over time, these day-to-day realities shape purchasing choices more profoundly than product literature.
Long-term supply contracts keep the factory in constant motion. Still, we place safety and waste management at the core of every campaign. Handling chlorinated intermediates means rigorous environmental controls—local regulators visit often and review our records closely. Operators understand the vigilance needed; teams run regular emergency drills and triple-check waste stream logs. Over time, iterative changes to reaction quenching and solvent recovery have cut hazardous output by over one-third. Each efficiency translates to a cleaner process and less impact outside the plant gates.
Our laboratory staff keeps sensitive detectors running to catch trace chlorinated byproducts before they can leave the facility. Final washing protocols use just enough solvent to achieve the required level of cleanliness, minimizing landfilled filter cake and solvent emissions. These improvements do more than tick a box; they reflect hard work in an industry where oversight grows yearly, and client audits ask tougher questions.
Much of the product’s legacy ties to its success as a platform for newer, greener crop-protection agents. Over a decade, we’ve fielded requests for tailored particle sizing, custom blends, or unique solvent systems in partnership with leading R&D groups. One product manager recalls partnering with an agrochemical innovator who scaled up a more precise formulation through minor tweaks to the starting material’s granulometry. Direct collaboration between the manufacturer and the formulation chemists trimmed months from the launch calendar and cut waste at the pilot stage.
Our technical team works side-by-side with process engineers during plant commissioning and troubleshooting. They know the impact that trace water or unintended crystalline form has on slurry stability or granule compaction. They understand the implications when a batch enters a spray dryer, ensuring the end material flows and binds as expected without gumming up critical machinery.
Producing 4-Chloro-2-Methyl-N-Acetoacet Anilide at scale brings its share of challenges. Supply chain pressure on chlorinated feedstocks tightens operating windows. Freight rates and seasonal power outages in export ports add uncertainty to logistics. But we take these as prompts to improve. Teams develop alternate raw material sources, run energy audits to lower baseline consumption, and push for automation upgrades that pinpoint issues before they reach scale. Engineers design more resilient filtration and drying systems that perform through the worst of a humid summer. Every improvement deepens product reliability for users.
We stay in close touch with end-users, keeping feedback loops short. Recent years have seen several rounds of joint troubleshooting with customers. By working on pilot plant runs or new application development directly, both sides learn quickly where potential bottlenecks hide. Shared knowhow helps avoid repeating mistakes from one end of the supply chain to the other. Refined analytical methods catch subtle impurities before they cascade into downstream headaches, and regular dialogue ensures alignment between desired specifications and achievable manufacturing limits.
Regulatory compliance drives many plant upgrades and documentation shifts. Crop protection clients face ever-shifting requirements; as their supplier, our own standards must anticipate regulatory tightening. We maintain detailed traceability in material sourcing and process logs, storing backup samples long after each lot ships out. Customers audit these records regularly. Our third-party partners run independent tests to verify product claims, and we publish full impurity profiles to preempt concerns about off-label uses or regulatory questions. These efforts keep trust strong and reduce market risk for all parties.
We also invest in on-site staff training covering chemical handling, toxicology, and safe material transfer procedures—practices that have contributed to a steady decline in reportable incidents over five years. Each small gain in contamination avoidance or operator safety cuts downtime and supports quality assurance, making for a safer and more predictable workplace.
Manufacturing scale matters in this segment. Small changes in process yield or energy consumption amplify across thousands of kilograms. We track and reduce solvent use, retrofitting reactors and solvent recovery systems over the years. These investments make a tangible difference—measured in cost per kilo and in community engagement on emissions and waste. In response to community feedback, we upgraded emission scrubbers and open space buffering. Local groups participate in annual tours and open forums, keeping lines of communication open and demonstrating that chemical production can coexist securely with neighbors.
Recycling streams for wash solvents and improving byproduct valorization have contributed to secondary revenue and reduced landfill. Each improvement started with an operator or R&D suggestion—never a theoretical best-practice but direct adaptation to problems arising daily on the plant floor.
We take pride in the days spent dialing in a process until the product flows just right, the hours spent collaborating with partner labs, and the unseen effort that goes into making every drum fit for its task. Years of customer stories reinforce that details—particle consistency, color, free-flow—translate into smooth downstream operations. These small victories span continents, with our material contributing to successful launches in diverse regulatory landscapes. Whether it’s a few extra hours of free-flow in a mixing hopper or a month saved in formulation screening, these facts reinforce the material’s value in real-world use.
Markets expect more traceability, lower environmental impacts, and ever-higher consistency from chemical suppliers. As new technologies emerge—automated sensors, inline monitoring, and AI-driven process tweaking—we position our facility to capture these benefits. Early pilots for real-time impurity scanning are under evaluation, offering promise to speed up corrective action and further polish product quality. Our in-house data and regular roundtables with global clients ensure feedback moves quickly into process improvements.
Evolving safety standards and shifting agricultural regulations shape routing, documentation, and finished product labeling. Dedicated teams review regulatory updates and attend stakeholder workshops, keeping ahead of compliance timelines. That way, buyers can focus on formulation and innovation instead of fighting upstream supply concerns.
What keeps our production crew sharp is knowing the difference that each shipment makes downstream. End-users build process maps and inventory targets around real delivery schedules and actual lot consistency. In response, our operations group coordinates with logistics partners and offers flexible loading times, minimizing delays during busy planting or R&D cycles. Seasonal peaks in orders—driven by agricultural calendars and new product launches—call for strong planning across production, warehousing, and dispatch.
Client technical teams and purchasing specialists visit often to share process changes or market demands on the horizon. We welcome these exchanges— operators and chemists learn as much from user anecdotes as from internal QC reports. Over time, accumulated field knowledge shapes product tweaks, shipment packaging, and support documentation. The result: a product shaped by need and reinforced by hands-on stewardship.
In the era of rapid agricultural innovation and tightening supply chains, intermediate chemicals like this one set the tone for downstream performance. Stable quality, clear documentation, and real-world usability always matter more than claims on a static PDF. Our investment in tight process controls, responsible sourcing, and practical feedback loops supports each customer in reaching their goals—whether it’s a new herbicide launch or a retool of legacy process lines. The lessons learned at every stage—from raw material intake to final product bagging—translate into fewer interruptions and more value added at every level.
4-Chloro-2-Methyl-N-Acetoacet Anilide stands out for those who’ve seen both the promise and pitfalls of specialty intermediates. It’s not just another chemical on the line—it’s the product of experience, continued investment, and a commitment to reliability that doesn’t waver. That commitment holds in every shipment, every sample, and every technical call, no matter where the product ends up in the world.
