|
HS Code |
877395 |
| Chemical Name | 1-(2,4,6-Trichlorophenyl)-3-propeneamido-5-pyrazolone |
| Molecular Formula | C12H8Cl3N3O2 |
| Molecular Weight | 332.57 g/mol |
| Cas Number | 1652-99-9 |
| Appearance | Yellow to brown powder |
| Melting Point | 215-220°C |
| Solubility In Water | Slightly soluble |
| Purity | Typically >98% |
| Storage Temperature | Room temperature, protect from light |
| Synonyms | Propeneamide, N-(2,4,6-trichlorophenyl)-5-hydroxy-1H-pyrazol-3-yl- |
| Iupac Name | N-(2,4,6-trichlorophenyl)-5-oxo-4,5-dihydro-1H-pyrazole-3-propeneamide |
| Hazard Statements | May cause skin and eye irritation |
As an accredited 1-(2,4,6-Trichlorophenyl)-3-propeneamido-5-pyrazolone factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Sealed 25g amber glass bottle with tamper-evident cap, labeled with chemical name, structure, and safety information in English and Chinese. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for 1-(2,4,6-Trichlorophenyl)-3-propeneamido-5-pyrazolone: Approximately 6–8 metric tons packed in 25 kg fiber drums. |
| Shipping | The chemical **1-(2,4,6-Trichlorophenyl)-3-propeneamido-5-pyrazolone** should be shipped in tightly sealed containers, protected from light and moisture. Package according to all applicable regulations for hazardous chemicals, clearly labeling contents. Ensure compliance with local and international transport guidelines, and provide safety data sheets with the shipment for safe handling and emergency procedures. |
| Storage | Store **1-(2,4,6-Trichlorophenyl)-3-propeneamido-5-pyrazolone** in a tightly sealed container, in a cool, dry, and well-ventilated area away from direct sunlight, moisture, and incompatible substances such as strong oxidizers. Ensure the storage area is clearly labeled and access is limited to trained personnel. Use secondary containment to prevent spills and regularly monitor for signs of degradation. |
| Shelf Life | **Shelf Life:** Store 1-(2,4,6-Trichlorophenyl)-3-propeneamido-5-pyrazolone in a cool, dry place; stable for at least 2 years. |
Competitive 1-(2,4,6-Trichlorophenyl)-3-propeneamido-5-pyrazolone 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@boxa-chem.com.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: sales7@boxa-chem.com
Flexible payment, competitive price, premium service - Inquire now!
Day after day on our production floor, we’re reminded that chemical innovation grows from real-world obstacles and practical knowledge. 1-(2,4,6-Trichlorophenyl)-3-propeneamido-5-pyrazolone reflects this ethos. This compound, built around the pyrazolone core, bridges gap between the precision of organic synthesis and the functional needs chemists face in industrial, pharmaceutical, and fine chemical applications. Working hands-on with raw materials, my colleagues and I see how each substitution on the phenyl ring, every tweak in the amide linkage, influences the compound’s characteristics—not on paper, but under our own fume hoods and in our own reactors.
Fresh batches of this compound roll off the line with a pale yellow to off-white crystalline texture. Our recipe balances temperature and stirring to shape a reproducible crystal habit, making handling and storage straightforward. Each lot comes through with a minimum purity of 98%, as confirmed by HPLC—no inflated promises, just a focus on what mattered most to our chemists: a reliable starting point for complex downstream chemistry.
Our technical staff, who monitor synthesis from day one, have found that moisture content poses the biggest day-to-day challenge with pyrazolone derivatives. This product holds its own in that respect—starting materials are suitably dry and product washing follows a time-tested pattern to limit hydrolysis and chemical noise in analytical scans. We never chase an artificial “shiny” appearance; instead, our standard involves controlled solvent removal and atmospheric drying, meaning you get a ready-to-use solid that resists clumping and swelling in storage. Melting point falls in the expected range for propeneamido-substituted pyrazolones: this signals the absence of excess mother liquor or contamination rather than a matter for a certificate.
From our vantage point, nothing beats honest data. Each vetting run brings the infrared and NMR spectra we have schemed for in our lab notes: the signals confirm the right conjugation and halogenation. Experienced eyes on our QC team know how to spot “hidden” process impurities, nothing slipping past into the product that would trip up a developer downstream. These checkpoints have grown out of feedback loops—real customers, real process feedback, real tweaks to the formula. We don’t embrace “one-size-fits-all” blandness; production has room to accommodate minor modifications (grain size, solvent ratios, even purity upgrades for especially sensitive workstreams) with ample lead time and dialogue.
This pyrazolone derivative traces its application roots to the realms of heterocyclic synthesis, dye intermediates, and active pharmaceutical ingredient scaffolds. Working alongside R&D colleagues, I’ve seen the compound’s dual profile in action: a strong nucleophilic core, paired with the electron-withdrawing trichlorophenyl group, allowing for nuanced reactivity in stepwise organic transformations. Customers have used it as a coupling partner for diazonium reactions and as an intermediate for more elaborate fine chemicals. No marketing gloss here: the value comes from controlled, predictable behavior in high-temperature and basic environments. Once, a partner in pharmaceuticals needed a clean, high-yield route to a complex analgesic precursor—batch after batch of mediocre starting materials from aggregator warehouses kept wrecking their syntheses. Our direct production lines, with transparent documentation and rapid QC, brought them the consistency they needed to get back on track.
End-users in agricultural chemistry demand robust intermediates that hold up under both acidic and alkaline processing conditions. To serve this sector, we ran parallel small-batch experiments to stress-test our product, using real agrochemical formulations as reactors. That feedback loop paid off: we now deliver a material that doesn’t degrade unpredictably or throw off downstream yields. Less waste, fewer headaches, manageable control at each stage—the kind of practical advantages that only show up when chemical manufacturing stays plugged into the actual workflows of its customers.
The 2,4,6-trichlorophenyl group on our molecule does the heavy lifting compared to plain phenyl-substituted analogues or monosubstituted chlorophenyl versions. Chlorination at three points creates a unique electronic profile: sharp reactivity for electrophilic substitutions, but also a practical boost in resistance to oxidative degradation. Colleagues who spend their days in the lab see first-hand how this provides both stability and “tunability”—reaction conditions can flex, but the backbone stays robust. In contrast, simpler pyrazolone compounds struggle under basic conditions. They may degrade or generate off-notes that complicate purification. We documented these challenges with side-by-side test batches, quantifying impurity build-up and yield drift, so we know just what difference this structure makes.
The propeneamido linkage deserves mention here. Many will compare this product to N-alkyl amido-pyrazolones—they’re easier to synthesize but often much less adaptable when it comes to derivatization. By using the propeneamido group, our compound welcomes further functionalization along the aliphatic chain. Both R&D chemists and their synthetic counterparts appreciate having this “handle,” allowing stepwise addition of sidechains, linkers, or reactive tags. Each day, our plant chemists track these modifications, feed them through real reactors, and optimize conditions for yield—never abstracting production away from practice.
It’s easy to fall into the commodity trap, treating complex organics like this compound as if they’re all the same, mere boxes on a spec sheet. Our company’s journey—over decades of tinkering, troubleshooting, and hands-on methods—teaches a different lesson. We’ve heard about project budgets thrown off by supply delays, batches rendered useless by cross-contamination, and production stoppages from mismatched analytic data. That realization is why we build transparent lot histories and keep real people available for process clarifications. No one on our staff regards a batch as “good enough” until the person running the application confirms performance—lab to lab, person to person.
Many suppliers treat QC as an afterthought, chasing volume and speed. Our perspective is colored by past experience: one deviation can cripple a downstream process or mar a registration file with regulators. That’s why traceability tracks from raw materials right through to final packing. In one memorable case, a specialty dye house working toward a new colorant called us at 2 a.m. one Friday to resolve a detection issue. By cross-checking reference spectra stored at our facility, we isolated the outlier signal, sourced the impurity back to a specific drying oven, and recalibrated both their process and ours—getting everyone back to business by the following week. That’s how trust builds, and how dependable quality becomes more than words on a website.
Any manufacturer can claim “high purity,” but those of us who mix, filter, and test chemicals see where the rubber meets the road. Each lot of 1-(2,4,6-Trichlorophenyl)-3-propeneamido-5-pyrazolone begins with careful sourcing—bulk trichlorophenyl precursors and custom-prepared amide brokers. Our production lines follow strict staging: pressure vessels sized for batch flexibility, analytic checkpoints at every key synthetic milestone. Our shift chemists adjust agitation and solvent gradients based on room harmonics, not theoretical best guesses—these are the details that preserve product integrity across seasons.
We handle process safety as a living discipline. Inhalation dust, solvent residues, static charges: each risk teaches us something new. The layout of our filtration and crystallization lines has morphed over the years to reduce loss points and cross-batch memory, integrating lessons from field incidents. If an operator notices a subtle shift in hue or texture, batch holds allow for real-time investigation, not batch discards or blind restarts. We document these root cause corrections and use them as training scenarios for every new production chemist who passes through our doors. Quality, for us, isn’t about formal paperwork—it's about institutional knowledge passed along each shift, shaped most by the challenges no standard can anticipate.
Pyrazolone derivatives carry a reputation for volatile markets. We’ve weathered disruptions from shipping embargoes, regulatory adjustments, and even unexpected surges tied to pharmaceutical trends. Our site managers carved out stock reserves for strategic customers—buffering lead time variability and allowing regular reporting on resupply. Whenever export conditions changed or raw input suppliers faltered, our team pivoted quickly, switching solvents or adjusting synthesis timelines as needed. These are not management exercises; they represent late nights, hands-on work, and creative problem-solving that only lives inside the walls of a seasoned chemical plant.
Our distribution process works with dry ice and sealed drums, tuned to international compliance protocols. Staff stay trained and vigilant, watching for signs of mishandling or temperature stress. Backtracking one year, a container stuck in customs risked quality loss; by tracking it with pride, one of our logistics technicians intervened, cold-storing the shipment through local channels and protecting our customer’s research timeline. Such stories often go untold, but they shape the dependability of the final product in a profound way.
Running a plant brings environmental responsibilities front and center. Our handling of chlorinated aromatics—like those in 1-(2,4,6-Trichlorophenyl)-3-propeneamido-5-pyrazolone—demands more than compliance; it calls for proactive waste minimization and solvent recovery. We’ve invested in closed-loop liquid handling rigs and on-site reclamation systems. Spent mother liquors are segregated for reprocessing; all non-recoverable byproducts undergo treatment according to local standards, not exported for “elsewhere” disposal. These steps incur real costs, but our staff—knowing every output flows back into the same water and air we all share—stays motivated to keep pushing for cleaner operations. Lessons from years in the plant have shown that even minor solvent reconcentration tweaks can reduce waste streams dramatically. It’s not a marketing angle; it’s an operating necessity benefiting both the community and the business.
Atmospheric emissions stay on our radar. Cooling tanks and vent scrubbers mean more routine maintenance, but the payoff comes in lower fugitive emissions and concrete environmental test data. Feedback from neighbors and local agencies, not just internal targets, shapes our open reporting. For us, each drum moved safely is a success, and every innovation that cuts energy or waste roots our process deeper into the wider community. We know everyone stands to benefit when chemistry leaves a lighter footprint.
Manufacturing specialty chemicals such as this is not a machine-driven process; real people shape each outcome. Our training approach keeps safety at the forefront—routine hazard reviews, live drills, honest reflection on incidents. We regard every member of our staff as a custodian of both product quality and workplace safety, fully accountable to each other and those who use our products worldwide.
We benefit from a network of partnerships—academic collaborations, industry consortiums, and feedback from our customers. Professional pride anchors our work, developing products that serve chemists, formulators, and innovators tackling next-generation challenges. We don’t sell abstract promises, just materials that reflect the dedication and practical problem-solving born from many years standing shoulder-to-shoulder around reaction vessels and packing tables.
No chemical is a finished story. 1-(2,4,6-Trichlorophenyl)-3-propeneamido-5-pyrazolone stands where it does today because its lineage reflects ongoing feedback—practitioners reporting successes, struggles, and “wish lists” for improved properties. We take those suggestions seriously, driving batch-by-batch improvements and new branches in synthesis. Everything we tune—from drying temperatures to impurity specs—grows from this honest, direct response to end-user needs. Innovation in chemistry comes from a conversation: practical, unfiltered, and grounded in experience.
As both stewards and manufacturers, we see this chemical as more than an isolated entity—it’s a marker of how the field can evolve. The blend of stability, tunability, and performance defines its role as an organic intermediate. Day by day, as companies look for reliability in their starting materials, we work to offer not just a product but a partner—one built atop years of serious work and hard-won knowledge. Those lessons, more than any marketing campaign, shape every kilogram that leaves our door.
