© 2026 Sinochem Nanjing Corporation,
All Right Reserved
|
HS Code |
847721 |
| Chemical Name | Cyanoethyl Acetate |
| Cas Number | 105-56-6 |
| Molecular Formula | C5H7NO2 |
| Molar Mass | 113.11 g/mol |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | 198-200°C |
| Melting Point | -47°C |
| Density | 1.070 g/cm3 at 20°C |
| Refractive Index | 1.4200 at 20°C |
| Flash Point | 88°C (closed cup) |
| Solubility In Water | Moderate |
| Vapor Pressure | 0.3 mmHg at 25°C |
As an accredited Cyanoethyl Acetate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | Cyanoethyl Acetate is packaged in a 500 mL amber glass bottle with a secure screw cap and clear hazard labeling. |
| Shipping | Cyanoethyl Acetate should be shipped in tightly sealed, chemical-resistant containers, clearly labeled according to applicable regulations. It must be transported as a hazardous material, protected from heat, sparks, and open flame. Ensure compatibility with other cargo, provide proper documentation, and use secondary containment to prevent leaks or spills during transit. |
| Storage | Cyanoethyl Acetate should be stored in a cool, dry, and well-ventilated area, away from heat sources, flames, and direct sunlight. Keep the container tightly closed and protected from moisture and incompatible substances such as strong acids, bases, and oxidizers. Use appropriate chemical-resistant containers, and ensure proper labeling and access only to trained personnel. Avoid storing near food or drink. |
|
Purity 99%: Cyanoethyl Acetate with purity 99% is used in electronic adhesive formulations, where it ensures high dielectric strength and minimal electrical leakage. Viscosity Grade Medium: Cyanoethyl Acetate of medium viscosity grade is used in fiber modification processes, where it provides uniform coating and improved fiber tensile strength. Molecular Weight 129.14 g/mol: Cyanoethyl Acetate with molecular weight 129.14 g/mol is used in specialty resin synthesis, where it allows predictable polymer chain growth and consistent product quality. Stability Temperature 80°C: Cyanoethyl Acetate stabilized up to 80°C is used in heat-cure sealant production, where it maintains chemical integrity during processing and prolongs sealant shelf-life. Melting Point -30°C: Cyanoethyl Acetate with melting point -30°C is used in cold-curing adhesive systems, where it facilitates application at low temperatures and yields strong bonds. Low Water Content (<0.5%): Cyanoethyl Acetate with low water content is used in high-precision inkjet ink manufacturing, where it minimizes nozzle clogging and ensures reliable ink dispersion. Refractive Index 1.416: Cyanoethyl Acetate with refractive index 1.416 is used in optical coating applications, where it provides consistent light transmission and enhanced optical clarity. Particle Size <50 μm: Cyanoethyl Acetate with particle size below 50 μm is used in microencapsulation processes, where it enables fine encapsulation and controlled active release. |
Competitive Cyanoethyl Acetate prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please call us at +8615371019725 or mail to admin@sinochem-nanjing.com.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: admin@sinochem-nanjing.com
Flexible payment, competitive price, premium service - Inquire now!
Cyanoethyl acetate doesn’t splash across headlines, but it shapes quiet revolutions in many sectors. Most people never give a thought to the materials underpinning daily essentials or clean technologies. After spending years watching fast-paced improvements in electronics and specialty coatings, one thing becomes clear—chemistry runs the show behind the scenes. Cyanoethyl acetate stands as a prime example. Its chemical formula, C5H7NO2, might not mean much to someone outside a lab, but dig a bit deeper, and you find it guiding the development of high-performance adhesives, resins, and specialty polymers. From circuit boards to the glue holding pieces together, this compound strengthens the bridges between innovation and reliability.
Back in early engineering days, many products relied on legacy solvents and esters that couldn’t keep up with the world’s push toward cleaner, stronger, or lighter materials. Cyanoethyl acetate produced under model CE-101, with a purity exceeding 98%, outpaces those old standards. Years of fine-tuning at bench level paid off—its compatibility with several polymer groups lets it slip into new and existing applications without fuss. The clean, colorless liquid flows easily, making it handy for blending and application. Its moderate boiling point and low viscosity make it a worker’s friend on the floor, not just on a datasheet.
Chemical markets ask for more every year—smaller batches, higher purity, specialty grades. Having worked on a chemical plant floor and crossed paths with every variety of raw material deliverable, I’ve seen firsthand just how disruptive a versatile intermediate like cyanoethyl acetate can be. Research teams lean on it for synthesizing cyanoethylated polymers that show up in everything from antistatic agents to medical adhesives. Its almost-neutral scent and quick-drying properties cut down complaints from staff and help meet strict workplace standards. Because it resists premature polymerization, waste shrinks and margins grow.
Years ago, many plants kept stacks of traditional acetates or acrylates around, which often came with tough shelf-life issues. Cyanoethyl acetate’s higher reaction selectivity streamlines inventory and lets process engineers cut down on unnecessary steps. It’s one of those rare cases where operational efficiency and output quality climb together. It’s not just chemistry for chemistry’s sake—it ticks boxes in practical labor management and regulatory compliance. While environmental rules grow sharper each year, this compound’s lower volatility compared to certain alternatives makes it a safer pick for sensitive jobs.
Looking at cyanoethyl acetate side-by-side with more common products like ethyl acetate or butyl acetate, the differences pop up in real life, not just in molecular structures. Ethyl acetate serves well as a solvent for paints or nail polish, but lacks the high reactivity needed in high-end adhesives. Butyl acetate brings a fruity aroma but doesn’t offer the same mix of workability and bond strength for industrial-grade resins. Cyanoethyl acetate’s unique molecular backbone—where the cyano group opens up opportunities for co-polymerization—means engineers gain more control over their end product.
Feedback from R&D workshops often centers around the trouble of balancing fast curing with strong final performance. Bringing cyanoethyl acetate into adhesive formulations changes this balance. The nitrile functionality hooks into longer polymer chains, resulting in cured materials that resist heat and solvents better than earlier blends. In my own small-batch tests, swapping in cyanoethyl acetate led to less yellowing and faster setting even at lower catalyst loadings. This advantage shows up anywhere repeatable quality and precision matter—think electronics, where a weak or inconsistent bond spells product recalls and loss of trust.
Most customers find their way to cyanoethyl acetate because they want dependable adhesives or resins. Beyond the surface, this compound quietly supports innovation in healthcare, high-tech manufacturing, textiles, and even specialty sensors. Biomedical engineers have turned to it for synthesizing polymers compatible with tissue adhesives, where strength must pair with biocompatibility. I’ve seen medical device production lines slow down from contaminants or unstable intermediates. With cyanoethyl acetate, fouling and cross-contamination fade, and output shifts into a higher gear.
In fiber production, its precision as an intermediate gives rise to high-tensile threads needed for next-generation flexible electronics and smart textiles. Textile engineers appreciate how its reaction profile delivers consistent yarn strength without leaving toxic residues, answering patient calls for hypoallergenic smart fabrics. I once walked through a facility exploring safer moisture control coatings for wearable tech, and the switch to cyanoethyl acetate intermediates cut their incident rate and raised worker satisfaction.
Cycling through supply chain meetings, the same story repeats—legacy chemicals disappoint as end-user expectations shift upward. Before cyanoethyl acetate, companies leaned hard on methyl or ethyl acrylate for synthetic resins. These compounds either fell short in terms of reactivity or generated too many side-products, translating into more downtime and product rejection. Cyanoethyl acetate, in contrast, delivers fewer side reactions, lets manufacturers dial in cross-link density, and produces a cleaner final product. Labs consistently note its sharper, more predictable performance, which simplifies troubleshooting and boosts through-line efficiency.
Cost savings seldom come from cutting corners, but from using better materials more wisely. For years, every failed batch or mid-line stoppage translated into thousands lost. Cyanoethyl acetate’s reduced reactivity toward moisture translates into less scrap and fewer frustrating delays. This reliability means companies meet ever-changing compliance or export needs with less re-training and fewer safety gaps. Collectively, this approach frees up technical teams to focus on developing the next round of breakthroughs, not on triage work or patching holes in process reliability.
Years past, “green” chemistry meant trade-offs: safer solvents often meant higher costs or weaker performance. Cyanoethyl acetate cuts through that legacy. Its low volatility and high flash point reduce fugitive emissions, making life easier for line workers and plant neighbors alike. Safety reviews in modern facilities have marked a corresponding drop in air sample issues and worker discomfort, supporting both regulatory compliance and strong retention of skilled hands.
Disposal headaches slow down many projects, especially as landfills and incinerators tighten rules. Cyanoethyl acetate, by behaving well in routine waste treatment streams, shrinks hazardous waste classifications and the need for expensive handling contracts. Compared with older nitro compounds, which produce problematic by-products, this ester produces far less hazardous residue—easing pain for both environmental engineers and local communities.
Working late in the plant, I watched how improved air quality boosted both morale and productivity. When management rolled out a new adhesive line based on cyanoethyl acetate, absenteeism from headaches and eye irritation dropped. With safer working conditions and less hassle on the regulatory front, costs go down and productivity climbs. This is the kind of chemical progress that improves day-to-day lives.
No material comes without its share of headaches. Cyanoethyl acetate isn’t immune—its higher reactivity demands respect on the handling side. Technicians moving from simpler acetates face a learning curve, particularly in storage and transfer. Tanks and lines need careful maintenance to avoid contamination, and operators must keep dilution rates precise. In my own experience consulting for a mid-sized adhesive plant, the shift to cyanoethyl acetate called for a short but intense burst of re-training and re-tuning of pumps and filters.
Importing and moving specialty chemicals brings a tangle of paperwork, too. Some jurisdictions flag any new ester as a regulatory risk, so compliance teams need to stay ahead of shifting standards. Early on, a client faced a shipment delay when documentation fell short—something that just wouldn’t happen with old-line solvents. By staying proactive and involving chemists and compliance staff early, those speedbumps turn into learning moments, not full stops.
Across growing economies, the push for higher-value manufacturing goes hand-in-hand with tougher environmental standards. Cyanoethyl acetate lets companies pivot away from dirtier baseline chemicals without giving up performance. Regional growth in electronics, medical devices, and high-end automotive parts all demand adhesives and coatings that stand up to heat, stress, and complex processing. As someone who’s followed both regulatory trends and tech breakthroughs, I’ve seen the value in compounds that can play nicely in both established and emerging markets.
Since its reactivity allows for tailored polymer properties, manufacturers can meet stricter customer demands with fewer formula tweaks. This compatibility becomes crucial when exporting—the same resin delivers consistent results whether the job lands in Asia, the EU, or North America. Customer complaints about off-spec shipments drop off, and reputations stay intact. In a world that values reliability, that counts for plenty.
Innovation doesn’t just rest on bright lab breakthroughs. It relies on practical, robust products that scale from the test bench to mass production. With cyanoethyl acetate in play, operations teams find it easier to test new blends or alter process runs fast. I once worked with a startup that was chasing lightweight sensor modules. Their big headache: finding an adhesive system matching the mechanical strength and electronic compatibility needed to survive both assembly and end use. By shifting core intermediates to cyanoethyl acetate-based polymers, they moved from proof-of-concept to full production far faster than competitors. Cost savings followed closely as product failures dropped.
The opportunity cost of passing up better raw materials shows up in lost contracts, regulatory fines, or public recalls. By choosing cyanoethyl acetate, firms hedge against those risks, winning points with both end-users and auditors. The material’s record for consistency and easy integration appeals to small labs and multinational producers alike, turning raw ideas into tangible products on store shelves.
Nothing in chemistry stands still, especially not as data drives smarter, more connected factories. Looking ahead, cyanoethyl acetate seems set to anchor new families of performance adhesives, copolymers, and fabrication aids. As more industries chase resilience and sustainability side-by-side, everyday products—phones, cars, clean energy systems, even patient care devices—will depend on smart intermediates like this one.
Plant engineers demand compounds that slot into complex supply chains and support automation. Cyanoethyl acetate gives them a tool for high-speed, high-accuracy manufacturing lines. It doesn’t just perform on the lab scale but works reliably across thousands of production cycles. Others have raised concerns about future supply, but careful sourcing and increased production capacity promise steady availability. As synthetic biology and environmental engineering join the mix, the role of cyanoethyl acetate will stretch even further, supporting recyclable and biodegradable polymers people can actually trust in day-to-day life.
Industry leaders and regulators agree—substances carrying legacy risks make little sense as new options emerge. Real-world data on cyanoethyl acetate supports its use over many common competitors in critical applications. Facilities switching to this compound report higher output and fewer incidents tied to volatility or workplace irritation. While safety always needs vigilance, the practical track record continues to favor its adoption.
From technical meetings to line-side feedback, the same points keep surfacing: better batch uniformity, higher yield, and fewer late-night maintenance calls all add up to stronger business outcomes. As factories move toward digital tracking and smarter monitoring, the easy traceability and stable handling profile of cyanoethyl acetate sync with these demands.
Earning trust in manufacturing doesn’t start with slogans—it starts with consistently delivering results. Cyanoethyl acetate, known for its purity and performance, earns credit in labs and production floors alike. Skilled process engineers prefer it for its combination of flexibility and reliability. Across my years advising clients, those who invested early in cleaner, more advanced intermediates saw reputations improve and customer satisfaction scores rise. It doesn’t just improve goods; it shapes safer, more agile workplaces and taller compliance marks.
Savvy buyers focus less on price per kilo than on the total impact of their supply chain choices. Engineers want proof a compound works under pressure. Throughout dozens of supply evaluations, I have noticed how quickly project teams open up to cyanoethyl acetate once they see live results—less downtime, smoother application, and easier adaptation to new requirements.
Product managers, on the other hand, value how fast this ester lets them deliver updates or improved formulas. Reduced regulatory burden on shipping and storage keeps projects nimble. As markets shift to shorter development cycles and heavier documentation, cyanoethyl acetate stands as a low-friction path to faster launches.
Years of shifting supplier landscapes taught me that reliable, adaptable chemicals can make or break a new product. Cyanoethyl acetate checks both boxes—it’s good enough to anchor next-generation formulas but forgiving enough that storage hiccups and minor upsets don’t derail progress. This flexibility turns risk into opportunity, letting creative teams trial new polymer blends without holding up deliveries.
Teams that pay attention to employee feedback and line-level performance see the value quickly: less spoilage, quicker changeovers, and more opportunities for both technical and commercial growth. In a world moving fast toward resource efficiency, these wins count as much as any line on the income statement.
Many companies still lean on ethyl acetate or butyl acetate because they’re known quantities—cheap, familiar, and decent for basic jobs. Cyanoethyl acetate, in contrast, outperforms them as a specialty intermediate, especially anywhere heat stability and custom reactivity make the difference between a niche product and an industry leader. It’s more than just a replacement; it leaders innovation into fields where old solvents stall.
For example, newer water-repellent finishes and specialty conductive adhesives need a base with strong resistance to moisture and environmental stress. Cyanoethyl acetate’s stronger bonding and flexible chemistry make a noticeable difference in final product performance. Experienced developers recognize where these benefits show up on the bottom line—fewer warranty claims, higher customer reviews, better approval rates from buyers with strict testing requirements.
Today’s compliance managers rarely have time to troubleshoot chemical mishaps. Cyanoethyl acetate’s stable handling and low toxicity profile allow quicker approval through many regional regulatory checkpoints. Unlike legacy nitro compounds or some acrylates that attract environmental scrutiny, this ester fits more smoothly into green compliance frameworks. Even as standards become more complex, companies using cyanoethyl acetate reduce risk without sacrificing product quality.
The story of cyanoethyl acetate is more than a technical shift; it’s about companies realizing the value of smarter, cleaner materials. Leaders in industries from electronics to medicine recognize how this compound turns pain points into potential. By trimming waste, improving process consistency, and boosting end-user safety, it creates room for innovation where mediocrity once stood.
In my own experience, every uptick in technical standards opened doors to higher returns and happier, healthier teams. What starts as a careful switch in the plant can ripple out, supporting better outcomes across the supply chain. Cyanoethyl acetate isn’t the only player in modern chemistry, but its reputation for solid, flexible performance lifts every operation daring enough to leave habits behind.
In the final tally, success in manufacturing doesn’t just belong to the loudest innovation but to the quiet advances that support progress across departments and markets. Cyanoethyl acetate proves its worth not by hype, but by the steady improvements it brings—stronger adhesives, cleaner resins, safer workplaces, and greener disposal. Fact-based assessment, hands-on experience, and a clear track record all point the same direction: this compound, though rarely celebrated, drives modern chemistry where it matters most. Those building tomorrow’s products would do well to pay attention to the quiet changes happening in their supply lines—the future depends on small, powerful differences like these.
