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HS Code |
846325 |
| Chemical Name | 1-Ethyl-1-Cyclohexanol Acrylate |
| Molecular Formula | C11H18O2 |
| Molecular Weight | 182.26 g/mol |
| Appearance | Colorless to pale yellow liquid |
| Density | Approximately 0.96 g/cm³ (at 25°C) |
| Refractive Index | Approx. 1.455 (at 20°C) |
| Flash Point | Estimated >90°C (closed cup) |
| Solubility | Low in water; soluble in most organic solvents |
| Functional Groups | Acrylate ester, secondary alcohol |
| Odor | Mild, characteristic |
As an accredited 1-Ethyl-1-Cyclohexanol Acrylate factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | 1-Ethyl-1-Cyclohexanol Acrylate is packaged in a 25 kg high-density polyethylene (HDPE) drum with a tamper-evident seal. |
| Shipping | 1-Ethyl-1-Cyclohexanol Acrylate should be shipped in tightly sealed containers, away from heat, sparks, and open flames. It must be transported as a flammable liquid, classified under relevant hazardous goods regulations. Ensure upright placement, proper labeling, ventilation, and compatibility with packaging materials to prevent accidental leaks or polymerization during shipping. |
| Storage | 1-Ethyl-1-Cyclohexanol Acrylate should be stored in a cool, dry, well-ventilated area, away from heat, direct sunlight, and sources of ignition. Keep the container tightly closed and store it in a dedicated chemical storage area, away from strong oxidizers and acids. Use containers made of compatible materials and protect from moisture and contamination to maintain stability and safety. |
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Purity 99.5%: 1-Ethyl-1-Cyclohexanol Acrylate with 99.5% purity is used in high-performance acrylic adhesives, where superior bonding strength and clarity are achieved. Viscosity 135 mPa·s: 1-Ethyl-1-Cyclohexanol Acrylate at viscosity 135 mPa·s is used in UV-curable coatings, where fast curing and improved surface smoothness are provided. Molecular Weight 182.26 g/mol: 1-Ethyl-1-Cyclohexanol Acrylate with molecular weight 182.26 g/mol is used in polymer synthesis, where controlled polymer chain growth improves mechanical properties. Refractive Index 1.49: 1-Ethyl-1-Cyclohexanol Acrylate with refractive index 1.49 is used in optical film production, where enhanced light transmission is obtained. Stability Temperature 150°C: 1-Ethyl-1-Cyclohexanol Acrylate with stability temperature of 150°C is used in heat-resistant plastics, where thermal integrity is maintained during processing. Melting Point -30°C: 1-Ethyl-1-Cyclohexanol Acrylate with a melting point of -30°C is used in low-temperature elastomers, where flexibility at sub-zero conditions is enhanced. Monomer Content < 0.2%: 1-Ethyl-1-Cyclohexanol Acrylate with monomer content below 0.2% is used in medical-grade resins, where low toxicity and regulatory compliance are ensured. Color (APHA) < 20: 1-Ethyl-1-Cyclohexanol Acrylate with color (APHA) below 20 is used in transparent coatings, where high visual clarity and aesthetic appeal are delivered. Water Content < 0.05%: 1-Ethyl-1-Cyclohexanol Acrylate with water content less than 0.05% is used in moisture-sensitive formulations, where product shelf life is significantly extended. Acid Value < 0.05 mg KOH/g: 1-Ethyl-1-Cyclohexanol Acrylate with acid value below 0.05 mg KOH/g is used in electronic encapsulation compounds, where electrical insulation reliability is improved. |
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In a market crowded with acrylate monomers, 1-Ethyl-1-Cyclohexanol Acrylate stands out for real reasons. This substance isn’t some everyday chemical—those who work in coatings, adhesives, and specialty polymer industries are searching for compounds that push past the routine. The leap comes from the unique makeup of the cyclohexanol backbone, which teams up with the acrylate group to deliver features not found in acrylic acid esters that have been on the market for decades.
The backbone of 1-Ethyl-1-Cyclohexanol Acrylate builds on both rigidity and flexibility—terms more than mere buzzwords here. The cyclohexyl ring delivers toughness that translates into scratch resistance, while the ethyl branch softens the molecule just enough to survive stress. The end result? Polymers formed with this acrylate maintain a balance between durability and flexibility, qualities that manufacturers keep chasing.
With an acrylate group ready for rapid polymerization, production lines don’t have to wait around. The process opens doors to faster curing temperatures, making life easier for engineers looking to speed up operations without sacrificing product quality. Quick cure times mean lower energy costs over months and years, not just hours and days.
People sometimes overlook what a single change in chemical structure can do for an entire end-use market. Take paints and coatings—most traditional options chalk up over time, losing sheen, and suffering under UV rays. Add 1-Ethyl-1-Cyclohexanol Acrylate to the mix, and real-world longevity improves. Housepainters and automobile refinishers can rely on finishes that last longer, stand up better to scuffs, and don’t break down under sun exposure.
Adhesive manufacturers are under the microscope as industries look for stronger bonds without trade-offs in safety or flexibility. This acrylate infuses enhanced adhesion strength, whether sealing the soles of running shoes, constructing automotive interiors, or bonding composites in electronics. These bonds hold up through temperature swings, moisture shocks, and repeated wear—a demand that grows as materials advance.
Carbon fiber and glass laminates see a clear benefit. In composites, the choice of resin sets the ceiling for mechanical performance. With this monomer in the resin mix, end-use parts gain impact resistance and dimensional stability, essential for industries like wind energy, aviation, and sports equipment. The payoff shows up in blades that spin longer, airplane panels that shrug off turbulence, or bike frames that don’t fatigue prematurely.
Every production chemist has a list of acrylates, and each comes with its own personality. Methyl methacrylate and ethyl acrylate serve as benchmarks—they’re widely tested, generally available, and predictable. But 1-Ethyl-1-Cyclohexanol Acrylate breaks from these old patterns. Its ring structure offers more bulk, changing the glass transition temperature in final polymers. That translates into coatings that don’t crack in winter or get sticky under the summer sun.
For anyone who’s mixed paints or adhesives, volatility and odor rank as ongoing frustrations. Some acrylates evaporate quickly and carry overpowering smells. Cyclohexanol derivatives reduce both evaporation rates and smells—something you notice as soon as you open the container. Workplaces become safer and more comfortable with fewer fumes, without relying solely on engineered ventilation. Healthier shop floors aren’t just a regulatory win, but a boost to morale and productivity, too.
Chemical resistance also takes a step up. Industrial floors, for example, often battle solvents, fuels, and cleaning agents. Standard acrylates can fail after repeated exposure, but this molecule forms crosslinked networks, creating surfaces less sensitive to abrasion and more resilient against daily spills.
Environmental safety is not a buzzword for future marketing copy; it is defining which products are chosen today. Traditional alkyl acrylates face criticism over emissions and persistence. 1-Ethyl-1-Cyclohexanol Acrylate can be synthesized with lower residual monomers, trimming down volatile organic compounds in the finished article. The impact reaches outside the laboratory, right to the jobsites and production lines, where users see cleaner air and fewer headaches.
Disposal concerns remain for most synthetic chemicals, but here is where polymer chemistry shows promise. By improving the performance-life balance, manufacturers cut waste—end products last longer, so replacement rates drop. While full biodegradability is still a large hurdle in the acrylate world, reducing consumption through longer service life is a practical, measurable step.
In chemical production, small shifts in storage conditions can mean the difference between smooth operations and costly shutdowns. The molecular design here brings a higher flash point compared to short-chain acrylates. This property takes some of the edge off flammability risks, translating to calmer safety meetings and improved insurance rates.
Resistant to hydrolysis, products built with this acrylate won’t break down quickly in humidity. Frequently, adhesives degrade where dampness creeps in—car windows, shoe soles, electronic assemblies—affecting lifetime and warranty claims. Building in this kind of hydrolytic stability matters in damp climates, and for companies, it curbs complaint calls and product returns.
Polymerization remains predictable and manageable, which simplifies line operation, regardless of location or season. That reliability means shops can stick to schedules, kicking variables down to a manageable level. Consistency in supply and end-use results grows from chemical design, not just regulatory paperwork.
It’s impossible to talk about industrial chemicals without weighing health effects. Every formulator checks toxicology data, but end users experience the real consequences of exposure. Short-chain acrylates have drawn attention for skin and respiratory irritation. In contrast, derivatives built on cyclohexanol cores tend to have a lower irritation profile, based on available in-vitro and real-world occupational data.
Site operators and lab staff have a stake in this, since day-to-day handling safety isn’t just about compliant glove-and-mask routines. Lower volatility and a higher molecular weight keep airborne concentrations lower. This means less need for heavy-duty masks in many scenarios and a smoother working day for teams in adhesives, specialty ink, or industrial paint shops.
Prolonged exposure studies show that repeated contact with many acrylates can lead to chronic problems, not just acute reactions. Selecting the less aggressive profiles of 1-Ethyl-1-Cyclohexanol derivatives makes it easier to protect team health, driving down lost days and recruitment headaches related to workplace discomfort or reactions.
Governments and regulators pay as much attention to acrylates as do customs officers. International markets demand clearer labeling, accurate emissions data, and transparent supply chains. Products that step ahead of regulatory minimums can enter new markets faster and avoid abrupt stops from new legislation.
In the European Union, REACH registration forces a hard look at monomer toxicity and environmental impact, so companies using safer, less volatile acrylates run into fewer compliance headaches. The same trend shows up in North America and East Asia, where sustainability rules are rolling in. By picking a compound with a favorable regulatory profile, suppliers avoid the scramble to reformulate or recall.
Big shifts in regulation don’t just affect chemical providers; downstream users—from paint shops to electronics assembly—feel the pressure. As acrylate choices tighten, companies that future-proof their processes by plugging in cleaner, safer compounds will likely see fewer supply disruptions.
Not all change gets driven by regulatory fines or marketing slogans. Talk to those who work with acrylates daily, and the feedback sways the needle. Technicians value fast cure times, but groan over short pot lives that waste material. Coating professionals grumble about shelf stability and yellowing. 1-Ethyl-1-Cyclohexanol Acrylate stretches shelf life and reduces yellowing compared to traditional acrylates. That boosts first-time right ratios out in the field and reduces the churn of returned goods.
Shop managers working with specialty coatings for demanding clients like aerospace and defense deal with audits and performance documentation. Showing a clear technical difference, with real field data on abrasion, flexibility, UV-resistance, and chemical durability—instead of just manufacturer’s claims—changes conversations with both inspectors and end clients.
End users have become more demanding. The difference between a product that holds up for a season and one that keeps its integrity for years makes or breaks reputations. Installers and finishers switch suppliers quickly when batches of traditional acrylate-based materials underperform. The loyalty for high-performance acrylates comes from user experience, not loyalty programs.
Manufacturing with specialty acrylates isn't cost-neutral. The unique structure means both raw material and processing expenses often climb slightly above those of everyday acrylates. Decision-makers have to weigh upfront costs against the longer-term cut in callbacks, product failures, and customer complaints. For companies with tight margins, this trade-off can cause debate. Yet, where warranty costs or support calls bite into the bottom line, investing in robust acrylates moves from “nice to have” to “strategic.”
Another area demanding attention is downstream compatibility. Not every legacy production line seamlessly integrates with new acrylate blends. Scale-up trials, resin compatibility checks, and test batches are routine. Technical teams benefit from working closely with vendors and technical service professionals—collaboration turns new chemistry into real products on time, not just in theory.
For startups and research labs, there’s always a balance between trying new materials and making sure every user—large or small—gets consistent supply. While 1-Ethyl-1-Cyclohexanol Acrylate has found a growing audience among mid-to-large manufacturers, smaller outfits sometimes face minimum order concerns, especially early in commercialization. This challenge shows up with nearly every new specialty monomer. Staying connected to distribution channels, and building relationships with flexible suppliers, can ease these growing pains and keep operations moving forward.
The next decade in material science won’t be shaped by sticking to the familiar. 1-Ethyl-1-Cyclohexanol Acrylate marks a smart step for industries under constant demand to innovate. Its chemistry takes proven acrylate utility and upgrades it for a world that wants better performance with fewer downsides. As every producer grapples with tighter regulations, climate impact, and worker health, moving beyond traditional monomers isn’t simply a trend—it’s a necessity.
Looking at the big picture, the product signals a shift in acrylate markets—from mass-produced basics to performance-focused, safer products. While the usual obstacles of cost, supply, and education remain, leaders in acrylic chemistry don’t wait for external pressure. They pilot new monomers, collect honest feedback from users, and drive the market forward by supporting those who need these benefits most.
With all these points in mind, it’s easy to see why technical teams, application specialists, and business owners are paying attention to 1-Ethyl-1-Cyclohexanol Acrylate as more than just another entry in a catalog—it represents a fresh baseline for where advanced manufacturing, safety, and real-world applications can meet.
