|
HS Code |
209644 |
| Chemical Name | 4'-Chloro-2',5'-dimethoxyacetoacetanilide |
| Molecular Formula | C12H14ClNO4 |
| Molecular Weight | 271.70 g/mol |
| Cas Number | 51835-97-1 |
| Appearance | Off-white to pale yellow solid |
| Melting Point | 153-155°C |
| Solubility | Slightly soluble in water, soluble in organic solvents |
| Purity | Typically ≥98% |
| Storage Conditions | Store in a cool, dry place; keep container tightly closed |
As an accredited 4'-chloro-2',5'-dimethoxyacetoacetanilide factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | White, opaque plastic bottle containing 100 grams of 4'-chloro-2',5'-dimethoxyacetoacetanilide, labeled with chemical name, CAS number, and hazard warnings. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL): Securely packed 4′-chloro-2′,5′-dimethoxyacetoacetanilide, 20 metric tons, drums or bags, on pallets, moisture-protected. |
| Shipping | 4'-Chloro-2',5'-dimethoxyacetoacetanilide should be shipped in a tightly sealed container, protected from light, moisture, and incompatible substances. Package in accordance with local, national, and international regulations for chemicals. Include appropriate hazard labels and documentation. Avoid extreme temperatures and physical damage during transport to ensure stability and safety. |
| Storage | 4'-Chloro-2',5'-dimethoxyacetoacetanilide should be stored in a tightly closed container, in a cool, dry, and well-ventilated area, away from sources of heat, ignition, and incompatible substances such as strong oxidizers. Protect from light and moisture. Properly label the storage container and keep it in a secure chemical storage cabinet designated for organic compounds. |
| Shelf Life | **Shelf Life:** 4'-Chloro-2',5'-dimethoxyacetoacetanilide remains stable for at least 2 years when stored in a cool, dry, and dark place. |
Competitive 4'-chloro-2',5'-dimethoxyacetoacetanilide prices that fit your budget—flexible terms and customized quotes for every order.
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After decades spent developing advanced intermediates for dye and pigment production, our line-up brings together molecules that have stood the test of time in both scale and demanding consistency. We take pride in the impact of 4'-chloro-2',5'-dimethoxyacetoacetanilide, a product shaped not just by chemical formulas but by routines of quality control, feedback from process engineers, and a long line of research benches. Our focus never drifts from the targeted needs of pigment manufacturers and specialty chemical formulators who rely on batches to perform the same, season after season. We are not traders; our relationship with every molecule runs from lab synthesis to ton-scale reactors, where every process cylinder and every filtration mesh counts.
This compound has found its niche among diarylide pigment intermediates, where structure defines its role. Developed for direct integration in a range of pigment chemistries, 4'-chloro-2',5'-dimethoxyacetoacetanilide reflects the experience of manufacturers who measure success in the finished color’s shade, opacity, and permanence. It lies at the heart of colorant synthesis for pigments demanding high chroma, strong dispersion, and resistance against weathering.
The chemical backbone marries a chloro substituent with two methoxy groups, giving process chemists flexibility when hitting exact hues in yellow pigment design. These modifications shift reactivities and solubilities, letting formulators tailor batch outcomes to specific coating or printing ink requirements. Using this intermediate allows pigment plants to steer production toward targeted shade indices and improve consistency across large lots—something only witnessed at scale, after hundreds of runs in a facility accustomed to minute-by-minute batch monitoring.
For anyone used to lab-scale chemistry, a successful reaction looks clean and easy in a round-bottom flask. On the plant floor, small variances snowball. Moisture content, crystal polymorph, and even slight inconsistencies in filtration stages start to tell a different story. We adapt our processes with all of this in mind. Years spent handling this molecule taught us the real drivers of success aren’t on paper—they’re in the behavior of the product in real process environments.
Our technical staff monitors not just purity levels but fine changes in crystal habit, free-flowing characteristics, and the way the slurry runs during downstream wash stages. Where pigment intermediates are prone to caking or unpredictable setting, we trouble-shoot with tweaks to drying profiles and filtration techniques. Our attention to these operational details emerges from feedback, occasionally blunt, from customers who supervise ton-scale operations.
Through direct manufacture, we observed how batch scale preparation unlocks subtle differences in pigment synthesis outcomes. Adjustment of reaction temperature profiles prevents over-chlorination or uncontrolled byproducts, which if left unchecked, can throw off downstream dispersibility or lightfastness. It’s these real-world production concerns—rather than theoretical purity alone—that separate intermediates prepared at small scale from those that consistently support industrial pigment synthesis.
We produce batches according to years of refined procedures. Our product typically appears as an off-white to slight beige powder with minimal fines, confirmed through laser diffraction measurement and hands-on experience with flow tests. Production lots undergo internal verification, targeting impurity levels below industry-accepted thresholds for diarylide pigment intermediates. Moisture content is kept tight, as uncontrolled water impacts the reproducibility of pigment coupling reactions.
As manufacturers, we have learned that even small drifts in assay or trace contaminants can lead to unexpected off-shades or physical inconsistencies in finished pigments—an especially costly outcome for customers delivering high-volume colorants to coatings or plastics plants. Our packaging and warehousing teams call out the importance of barrier lining storage conditions, since the product’s delicate methoxy groups require careful moisture monitoring. Physical phenomena like compaction or bridging are best controlled with batch-wise transfer checks and lot rotation, another insight shaped by years of hands-on shipping and inventory management.
Anyone deeply involved in pigment chemistry knows there is no single ‘best’ intermediate—only the right fit for given color and application demands. 4'-chloro-2',5'-dimethoxyacetoacetanilide carries distinct advantages when compared to other acetoacetanilides due to its chloro group, which pushes electronic effects during azo coupling, and dual methoxy substituents that impact stability and solubility. Manufacturers who require top performance in full-shade diarylide yellows choose this intermediate because it supports brighter, cleaner tones than parent acetoacetanilide structures.
Chemistry aside, practical matters count just as heavily. Our learning shows that pigment plants using less selective intermediates wind up with a broader product spec, leading to more sorting, rework, or—on bad days—scrappage of batches that drift outside target shade. Consistency becomes critical when a product ships to end-users operating at massive scale, such as printing ink or plastics compounding lines. That reliability requires discipline in both the process chemistry and supply chain management, lessons stained into our standard by many years of continuous feedback from application labs and production lines.
Over recent years, our customers have placed increasing focus on reducing waste, managing process effluents, and seeking intermediates that help cut solvent demand or hazardous byproduct formation. As manufacturers, we looked at green chemistry not just from regulatory pressure, but after seeing first-hand how more predictable intermediates help reduce off-spec pigment generation and lower the burden on purification equipment downstream. This intermediate fits those needs, since it enables controlled coupling reactions under milder conditions, slashing both heat and solvent requirement compared to less substituted alternatives.
On our site, we run life cycle impact assessments—not just for regulatory paperwork, but to find efficiencies in water and power use. Lessons come from grinding through utility runs, equipment maintenance windows, and waste water management statistics. By dialing in processes for 4'-chloro-2',5'-dimethoxyacetoacetanilide, we’ve seen drops in both energy cost per kg produced and in the downstream scrubber loading, particularly during peak pigment manufacturing campaigns in the summer.
The credentials of 4'-chloro-2',5'-dimethoxyacetoacetanilide stretch far beyond analytical purity. It underpins the quality of high-performance yellow diarylide pigments used in automotive coatings, plastic color concentrates, and advanced printing inks. Production chemists ask for it by name when seeking precise C.I. Pigment Yellow 13, 14, or similar classes, counting on it to anchor color values across global product lines.
Lab teams in both established and emerging markets have reported that pigment synthesis outcomes show tighter color variation, easier grinding, and improved light stability with this intermediate versus less refined or less tailored options. Our commitment grows from hearing first-hand how downtime and off-grade shipments sink productivity, forcing pigment plants to juggle extra processing steps or urgent returns. Consistency has become our brand’s reputation—built from measuring, blending, packing, and dispatching ton after ton with a stubborn devotion to what happens after the product leaves our gates.
Real-life manufacturing rarely follows textbook recipes. Over the years, we’ve combated contamination, material build-up, emulsion failures, and packaging breakages that textbooks seldom address. Improper segregation on the factory floor, unexpected tank residues, or air leaks during vacuum drying can all introduce headaches, showing up weeks later as subtle color defects or slower dispersions at the customer’s site. To address these problems, we structured preventive maintenance routines, invested in closed-system transfer, and set up feedback loops so each shipment reflects lessons from the previous lot.
Another challenge arises from global logistics shocks. Raw material outages and port congestion can bring even the most efficient plant to a crawl. By vertically integrating our sourcing and working closely with upstream suppliers, we buffer against delays or quality swings in precursors. In-house labs keep live reference samples of prior lots to ensure traceability, enabling fast troubleshooting—often catching a process drift before a big batch is on the trucks. It’s an approach learned through necessity, not boardroom planning.
Unlike trading houses or repackagers, a manufacturer lives and breathes the batch process. The importance of in-process analytics, pH control in diazotization, and near-line spectrophotometry becomes much more than laboratory routine—it’s what allows customers to trust our material in thousands of pigment synthesis runs. Our team avoids short-cuts when washing and drying, since we’ve documented how even low-level residues shift pigment performance in certain binder systems.
Regular batch audits, operator upskilling, and capital upgrades to reactor controls reflect years of lessons learned running full-load campaigns. Take reactor fouling: minor as it seems, a fouled jacket subtly reduces heat transfer, inviting uneven conversion and poor batch reproducibility. Process engineers spot the signs early during campaigns involving 4'-chloro-2',5'-dimethoxyacetoacetanilide and log data so cleaning cycles and inspection protocols can be refined further. Equipment reliability connects directly to both product quality and customer trust, and it’s a lesson cemented with each annual overhaul.
Old hands love to point out that there’s always something to improve. True enough. From the first glass-lined reactor to today’s distributed process controls, each evolution in the production environment reveals more about the molecule’s behavior. We track temperature gradients, pressure spikes, and even the way a batch mixes under different agitation regimes, then feed data into our next improvement cycle. This culture of measurement and feedback matches what our customers expect from a true manufacturing partner.
Over the years we’ve also adopted greater automation in weighing and blending feedstocks, introduced RFID-tagged shipment tracking, and invested in new filter dryer technology. These improvements don’t just tick off boxes for quality audits—they keep the whole supply chain running smoothly so waste is minimized and orders are fulfilled even during periods of high demand. Customers value the reduced risk and greater transparency this brings, especially in markets where pigment quality and supply can determine competitive advantage.
It’s a running theme: production needs drive innovation, not just cost saving or policy compliance. Our own technical specialists sit with application chemists, sometimes late into the night, dissecting root causes for shade drift or physical stability loss. Redesigns to the process flow, raw material screening, or wash protocol often spring from a troubleshooting session after a surprise in the field. The pursuit of tighter particle size control, cleaner color index outcomes, and improved moisture resistance reflects routines built over years of real-world production headaches and customer problem-solving.
Adjustments in particle size control, driven by real feedback, now let our customers achieve faster wet-out, easier dispersion, and less pigment "settling" in both water- and solvent-based systems. Switching process solvents, improving nitrogen blanketing, or refining granulation—for us, these changes are not marketing pitches, but methodical responses to batch inconsistencies observed in real pigment plants. So the product is shaped and reshaped by direct customer use and feedback, often outpacing laboratory ideas or standard reference literature.
Markets continue to shift. Demand for brighter, more durable pigment classes in plastics, coatings, and specialty ink markets only grows. Stronger regulatory developments—often global in scope—mean our customers now look for more than purity numbers; they expect a partner who understands lifecycle, compliance, and performance. We fortify our own supply chain resilience, emphasize product stewardship, and stand ready to help R&D teams incorporate improved intermediates into both new and legacy pigment systems.
Field trials help us gather use-case feedback that’s impossible for traders or resellers to obtain. Changes in feedstock sourcing, regulatory lists, or downstream formulation often signal the need for another production trial, sometimes long before regulatory shifts ripple through the market. We meet with formulators to map how a subtle shift in intermediate performance trickles down to global supply, influencing color control, waste rates, or production downtime in final pigment manufacturing. This loop seals our commitment to continuous improvement and close partnership with the real experts—those who run the plant floors, color laboratories, and manufacturing lines.
Each shipment carries more than the sum of assay, moisture, and color stats. Our batches reflect years of feedback—sometimes critical or pointed—from buyers, plant managers, and R&D partners who stake their own brands on performance. Achieving this level of trust takes more than meeting written specification—it grows from transparency, field-based support, and follow-through whenever things go wrong. We encourage our customers to raise questions, request data, or walk through our plants during audits. It’s from this open dialogue that our methods evolve and product attributes adapt to ever-changing real-world demands.
Through the hands-on development, constant monitoring, and practical adjustments that define manufacturer expertise, 4'-chloro-2',5'-dimethoxyacetoacetanilide stands as more than a product code: it’s a solution validated in day-to-day industry use and advanced along the feedback loop that only true manufacturers experience. Direct engagement with operational hurdles and evolving applications makes our commitment to customers ever stronger—refined not in the marketing office but on the factory floor, one batch at a time.
