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HS Code |
393232 |
| Chemicalname | Acrolein Cyanohydrin Acetate |
| Casnumber | 14660-16-5 |
| Molecularformula | C6H7NO3 |
| Molecularweight | 141.13 |
| Appearance | Colorless to pale yellow liquid |
| Boilingpoint | 88-90°C at 2 mmHg |
| Density | 1.147 g/cm3 |
| Solubility | Decomposes in water |
| Refractiveindex | 1.448 (at 20°C) |
| Odor | Pungent, irritating |
| Storageconditions | Keep cool and dry, store tightly closed |
| Stability | Unstable, decomposes gradually, especially when moist |
| Uses | Intermediate in organic synthesis |
As an accredited Acrolein Cyanohydrin Acetate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | A 25-gram amber glass bottle with a tightly sealed cap, labeled “Acrolein Cyanohydrin Acetate,” featuring hazard and handling warnings. |
| Container Loading (20′ FCL) | Container Loading (20′ FCL) for Acrolein Cyanohydrin Acetate: Packed in approved drums, securely palletized; max net weight: 14-16 metric tons. |
| Shipping | Acrolein Cyanohydrin Acetate should be shipped in tightly sealed containers, protected from light, heat, and moisture. Transport must comply with hazardous material regulations. Use appropriate labeling with hazard warnings. Ensure packages are secure to prevent leaks, and handle with care to avoid exposure, as the chemical is toxic and potentially unstable. |
| Storage | **Acrolein Cyanohydrin Acetate** should be stored in a cool, dry, well-ventilated area, away from heat, sparks, and sources of ignition. Store in tightly sealed, chemically compatible containers. Isolate from oxidizers, acids, bases, and moisture. Clearly label containers and keep away from direct sunlight. Use secondary containment and ensure access to spill containment and emergency equipment. |
| Shelf Life | Acrolein Cyanohydrin Acetate has a short shelf life; it is unstable and decomposes upon prolonged storage, especially at elevated temperatures. |
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Purity 99%: Acrolein Cyanohydrin Acetate with purity 99% is used in pharmaceutical intermediate synthesis, where high purity ensures optimal yield and minimized by-product formation. Molecular Weight 129.11 g/mol: Acrolein Cyanohydrin Acetate at molecular weight 129.11 g/mol is used in fine chemical manufacturing, where precise molecular weight facilitates predictable reaction outcomes. Boiling Point 150°C: Acrolein Cyanohydrin Acetate with boiling point 150°C is used in specialty solvent formulations, where thermal stability enhances process reliability. Stability Temperature 25°C: Acrolein Cyanohydrin Acetate stable at 25°C is used in laboratory reagent storage, where ambient stability extends shelf life and usability. Viscosity 1.5 mPa·s: Acrolein Cyanohydrin Acetate with viscosity 1.5 mPa·s is used in organic synthesis reactions, where low viscosity improves mixing and reaction kinetics. Particle Size <10 μm: Acrolein Cyanohydrin Acetate with particle size below 10 μm is used in catalyst preparation processes, where fine particle distribution allows enhanced catalytic activity. Melting Point -15°C: Acrolein Cyanohydrin Acetate with melting point -15°C is used in temperature-sensitive formulations, where low melting point assists in processing flexibility during blending. Water Content <0.1%: Acrolein Cyanohydrin Acetate with water content below 0.1% is used in moisture-sensitive synthesis procedures, where reduced water content prevents unwanted hydrolysis and degradation. Refractive Index 1.425: Acrolein Cyanohydrin Acetate with refractive index 1.425 is used in optical resin production, where consistent refractive properties enable precision in optical performance. Storage under Nitrogen: Acrolein Cyanohydrin Acetate stored under nitrogen is used in controlled-environment chemical manufacturing, where inert atmosphere preserves chemical integrity and prevents oxidation. |
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Manufacturing Acrolein Cyanohydrin Acetate in-house gives us a front-row seat to every batch's performance, stability, and chemistry under real-world conditions. Our team dives deep into process control for every synth run, ensuring every lot meets tight standards for color, purity, and content. We do not ship until the liquid runs clear in appearance and lands within spec for acrolein cyanohydrin content. By committing to repeatability, we take uncertainty out of planning and production for our customers.
Taking care of the synthesis ourselves means we follow the journey of raw acrolein and cyanide reactants up close, always watching for critical parameters. We put energy into impurity management because side reactions can quickly ruin a whole batch, especially with acetate esters this sensitive. On a practical level, that means you don’t see random haze, off-color, or mystery compounds in our outgoing drums. Fewer surprises on arrival can save time in testing and scale-up.
Acrolein Cyanohydrin Acetate, Model AC010, delivers a consistent liquid at room temperature, tailored for regulated lab handling and industrial application. Our standard output falls within 99.5% minimum content by mass, and water levels remain low enough to protect against hydrolytic breakdown during transport and long-term storage. We validate every batch for residual free acid and for aldehyde content, since trace impurities can trigger unwanted shifts in stability downstream. If an application demands tighter specs—say, for pharmaceutical or specialty intermediates—we run extra purification steps.
Users in agrochemicals, fine chemicals, and pharmaceutical intermediates value reproducibility in the acetylated cyanohydrin family. Our Acrolein Cyanohydrin Acetate moves beyond the performance ceiling of standard hydrocarbon cyanohydrins, where volatility and reactivity can sabotage reaction planning. The acetate group brings a more manageable release of the parent cyanoalcohol compared with the raw hydroxy form—a critical advantage where handling risk, reactivity control, and regulatory compliance intersect.
Direct-to-user shipment from our plant, rather than through a resale channel, strengthens accountability for logistics and chain-of-custody on this class of hazardous material. The liquid meets packaging compatibility requirements for mild steel or fluoropolymer-lined containers, and storage under cold conditions limits the risk of hydrolysis or polymerization, both of which would degrade material quality. We maintain full traceability on each shipment, so anyone running a scale-up or regulatory review can get all batch records and testing data.
Other acetate esters or related cyanohydrins may offer similar intermediate reactivity or functional group availability, but this acetylated acrolein adduct draws a straight line between stability and high conversion efficiency for downstream transformation. Users avoid the instability and gas evolution typical of non-acetylated acrolein cyanohydrins, while also reducing exposure incidents associated with more volatile forms. The chemical backbone supports selective nucleophilic attack, often yielding cleaner reactions with fewer side products. We have partnered with process chemists on custom scales: they report tighter mass balance, cleaner phase separation, and easier purification steps compared to non-acetate forms.
We have produced both the acetate and unesterified (free hydroxy) forms to meet niche customer needs, but the acetate offers a significant risk reduction in both plant and shipping environments. Acrolein itself ranks as a high-hazard material in transport, while its cyanohydrin inherits much of its volatility and toxicity. Conversion to the acetate ester drops the vapor pressure and increases solvent compatibility, making handling protocols less stringent and environmental emission controls more straightforward.
Compared with propionaldehyde cyanohydrin acetate or crotonaldehyde analogs—compounds that sometimes find use in similar chemical syntheses—Acrolein Cyanohydrin Acetate confers distinctive reactivity because its unsaturated aldehyde carbon is more accessible, supporting reactions where a more aggressive nucleophile or a lower activation threshold is required. While some competitors advertise parallel esters derived from other aldehydes, our experience with acrolein-derived cyanohydrins in pharmaceutical and fine chemical synthesis finds better adaptability to customized downstream steps. Many of our customers have switched after their own evaluation phases determined that alternative esters introduced unwanted side reactions or unpredictable hydrolysis profiles.
In the plant, our operators monitor critical control points not just for purity, but also for things that do not show up on standard citrate titration or GC-FID alone, such as chromophore development or microemulsion phase separation, which can foreshadow instability. The acetate ester brings down that instability risk; the material sits reliably in the liquid phase through sub-ambient storage up to standard room temperature. There is no need to dissolve in high-toxicity solvents just to get batch-to-batch metering right, which cuts time off the scale-up timeline for customers who demand tight project schedules.
Handling Acrolein Cyanohydrin Acetate day after day, our team has learned that small details in packaging and shipping add up. Bulk isotainers and lined drums allow for safe transfer in both small-lot and multi-ton volume. We never rely on third-party repacking, and we refuse old or worn containers: those can let in trace water or air, which starts a slow path toward degradation. What matters as much as the spec sheet are day-to-day things: cap integrity, climate control, and time from production to delivery.
On-site, we have dialed in workflows for decanting, subsampling, and composite blending. Acrolein Cyanohydrin Acetate does not respond kindly to abrupt temperature shifts, so process purging with inert gas helps drag out shelf life during storage and imparts more confidence for international shipping. Reactions involving this product show increased yield on average, a fact our technical staff have documented by running side-by-side comparisons against non-acetylated alternatives for key pharmaceutical intermediates.
Our on-the-ground feedback from users reads similar: The acetate ester improves repeatability across a range of synthetic transformations. Users see more robust mass transfer and fewer pump or seal issues thanks to lower volatility versus the unesterified cyanohydrin. During purification steps, the acetate group can be selectively removed under mild acid or base conditions to regenerate the parent cyanohydrin, or onward hydrolysis allows direct access to glycolic or acrylic intermediates. Flexibility here enables users to fine-tune target molecule structures or access unique functionality, especially where oxidative or conjugate addition steps matter.
We keep compliance top of mind in each phase of production and shipment. Toxicity concerns from free cyanide and acrolein residues drive our focus on secondary containment, staff training, and validated safety data sheets. On-site emergency response drills and containment protocols are part of our presentation to new employees and shipping partners. Container closure integrity testing and leakage simulation scenarios help us document fitness for purpose before anything leaves our site.
Shipping Acrolein Cyanohydrin Acetate involves navigating a regulatory environment where each destination country brings a stack of requirements—labeling, hazard communication, and waste handling among them. Our approach includes documentation for UN packing group assignments and proper labeling for marine and air-freight modes. Process validation for each step prevents regulatory hold-ups and keeps audit findings at bay.
We work directly with downstream process managers to adapt documentation for in-plant compliance, so users in Europe, North America, and East Asia can focus more on productivity and less on explaining unfamiliar compounds to inspectors. The clear advantage of producing the acetate ester in-house comes in the reduced handling incident rate versus previous cases where unstable or mis-packaged alternatives caused disruptions. Absence of third-party logistical chains means every drum and bulk container travels with source traceability, including full analytical documentation for each batch code shipped.
We recognize the scrutiny applied to all cyanide, acrolein, and acetate derivatives in terms of environmental impact. Water solubility, hydrolysis rates, and end-of-life management factor into both regulatory review and public concern. By producing tighter, more stable acetate esters, we limit volatile emissions and off-gassing in storage or transit. Our downstream partners have fewer waste treatment issues, as post-reaction hydrolysis of the acetate group can be performed under controlled and closed systems, minimizing the risk of airborne or aqueous contamination.
Minimizing run-off, reusing solvents, and maintaining closed transfer protocols across our plant help us bring down the footprint per ton manufactured. Investing in real-time monitoring of effluent streams catches excursion events in-process, not after the fact. We partner with responsible waste handlers who specialize in both cyanide and aldehyde residual clean-up, with full documentation for cradle-to-grave chemical accountability.
Some customers express concern about environmental persistence of both acrolein derivatives and acetate esters. By producing a high-purity acetate, we reduce contaminant buildup in waste streams and improve downstream treatability, which makes routine compliance checks, site audits, and environmental reporting more manageable for operators using our product. The reduction in free volatile organics and ease of post-use hydrolysis directly reduce site-specific air and water emissions—a tangible result we confirm by comparing process plant records before and after switching to Acrolein Cyanohydrin Acetate.
We keep a close connection with academic and industrial researchers developing new routes for high-value intermediates, specialty resins, and pharmaceutical actives from this class of compound. Our chemists participate in collaborative studies assessing new applications for Acrolein Cyanohydrin Acetate, especially those focusing on regioselective cyanation, carbon-carbon bond formation, or even new catalyst systems that benefit from this acetate-protected group.
A few years ago, one of our university research clients began using our acetate ester in a route to rare beta-amino acids. Prior attempts using the parent cyanohydrin failed due to quick degradation, but the acetate form improved both storage stability and reaction selectivity. We tracked yield, purity, and impurity profiles across several runs and documented both lower side product levels and more robust process performance.
On the industrial side, several early-phase agrochemical projects required an acrolein cyanohydrin source that could bridge raw material storage and complex, multi-step synthesis. The acetate ester’s low volatility ensured worker protection and enabled on-demand deprotection within flows that involved both batch and continuous operations. Each time a customer scales up to full production, we open our plant records—shipping logs, analytical data, packaging specs—so process managers can address supply chain audit questions quickly.
Having 24-hour technical support is more than a marketing line for us. Teams who handle hazardous esters at scale want live support on transport, storage, and process issues. We provide technical consultations before shipping to clarify batch-specific quirks or compatibility questions. If a downstream user faces an unexpected phase separation, pH drift, or shelf life shortfall, we stay connected until the issue is resolved, drawing on both front-line manufacturing experience and strong ties to analytical laboratories.
Over the last decade, our plant has seen its share of challenges, from raw material bottlenecks to sharp swings in end-user demand. By focusing exclusively on manufacturing and not trading or third-party reselling, we have had the flexibility to quickly adjust batch sizes and product grades to real-world client needs. Users value this because delays in chemical supply impact costs far upstream and down.
Each year, we help process engineers rethink their reaction setup or raw material schedules, sometimes bringing in our synthesis team for joint troubleshooting. This adds up to more than a simple supplier-customer relationship. It builds a network of operational experience around Acrolein Cyanohydrin Acetate, improving the odds of successful scale-up, regulatory approval, and repeat business across both emerging and established markets.
Demand for acetate-protected intermediates like Acrolein Cyanohydrin Acetate continues to rise as customers pursue more robust synthesis pathways, better risk control, and fewer surprises in regulatory reporting. Our direct manufacturing model lets us spot shifts in impurity demand, packaging compliance, and analytical standards long before they hit the open market. We upgrade production lines and expand capacity only after field trials and dialogue with serious users.
Continued investment in analytical chemistry and process engineering keeps our offerings competitive while reflecting practical feedback from hundreds of plant runs and thousands of kilograms passed through our lines. New markets ask new questions about stability, compatibility, and post-reaction handling, and we bring those real questions back to our chemists and floor operators. By keeping accountability and data flow in one loop, we reduce the guesswork and make Acrolein Cyanohydrin Acetate a reliable, performance-driven staple for chemical synthesis.
Acrolein Cyanohydrin Acetate stands as the result of relentless process optimization, operational focus, and two-way communication between manufacturer and user. Every kilogram shipped represents not just raw chemistry, but years of hands-on problem solving and open dialogue with industrial and research partners. Looking forward, the future of complex synthesis depends on reliable, well-managed intermediates—the kind that only manufacturers intimately familiar with every step of their own production process can provide.
