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HS Code |
540169 |
| Product Name | 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate |
| Purity | 99% |
| Cas Number | 222889-12-9 |
| Molecular Formula | C9H14O4 |
| Molecular Weight | 186.21 g/mol |
| Appearance | Colorless to pale yellow liquid |
| Boiling Point | No data available |
| Density | Approximately 1.11 g/cm3 |
| Refractive Index | No data available |
| Solubility | Mixes with common organic solvents |
| Flash Point | No data available |
| Storage Temperature | 2-8°C, protected from light and moisture |
| Synonyms | 2-Methyl-3-hydroxytetrahydrofuran methacrylate |
| Category | Methacrylate monomers |
As an accredited 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%) factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The chemical is packaged in a 100 g amber glass bottle, sealed with a screw cap, and labeled with safety and purity information. |
| Container Loading (20′ FCL) | 20′ FCL can load approximately 14 metric tons, packed in 200 kg HDPE drums, totaling about 70 drums per container. |
| Shipping | 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%) is shipped in tightly sealed containers under ambient or cool, dry conditions. Packaging complies with chemical transport regulations to ensure safety and product integrity. Proper labeling, hazard precautions, and documentation are provided. Handle with care due to potential flammability and reactivity. Expedited shipping available upon request. |
| Storage | Store **3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%)** in a cool, dry, well-ventilated area away from direct sunlight, heat, and sources of ignition. Keep container tightly closed and protected from moisture. Store away from incompatible materials such as strong oxidizing agents and acids. Use only in a chemical fume hood, and avoid prolonged exposure to air to minimize risk of polymerization or degradation. |
| Shelf Life | Store 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%) tightly sealed, cool, and dry; typical shelf life is 12–24 months unopened. |
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Purity 99%: 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%) is used in UV-curable resin systems, where high purity ensures enhanced polymerization efficiency. Molecular Weight 158 g/mol: 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%) is used in biomedical hydrogels, where precise molecular weight enables controlled swelling behavior. Low Viscosity: 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%) is used in advanced 3D printing resins, where low viscosity facilitates improved print resolution. Refractive Index 1.45: 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%) is used in optical coatings, where defined refractive index promotes optimal light transmittance. Melting Point -10°C: 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%) is used in cold-processable adhesives, where low melting point enables easier processing at reduced temperatures. Stability Temperature up to 120°C: 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%) is used in heat-resistant polymer formulations, where stability at elevated temperatures maintains mechanical integrity. Monomer Functionality: 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%) is used in specialty copolymer synthesis, where reactive methacrylate groups enable high crosslink density. Hydroxyl Content 10%: 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%) is used in polyurethane prepolymer modification, where hydroxyl functionality enhances flexibility and adhesion. Solubility in Polar Solvents: 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%) is used in waterborne coatings, where high solubility ensures uniform dispersion and smooth film formation. Shelf Life 12 Months: 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%) is used in industrial monomer storage, where extended shelf life guarantees consistent product quality over time. |
Competitive 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%) prices that fit your budget—flexible terms and customized quotes for every order.
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As long-time chemical manufacturers, we have watched the landscape for specialty methacrylates change over the years. Demands come and go, but some molecular designs solve problems that resurface in every generation of product development. Our own weight of experience shapes how we work with 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate (99%). From the first batch to the most recent run, consistency takes precedence. We handle every stage under one roof, overseeing raw material intake, process controls, and product finishing. Our production team draws on decades of technical know-how, trusting their senses along with instruments.
This methacrylate derivative springs from an ongoing need for clearly defined backbone flexibility in formulations that demand both performance and processability. The structure—essentially a cyclic ether lactone with a methacrylate handle—delivers features that broader market alternatives tend to miss.
Monomers in this rough family include THF-methacrylates or simple hydroxyalkyl methacrylates. Ours occupies a sweet spot between steric protection and reactive openness. The 99% assay reflects not just chemical purity on the certificate, but the actual control we maintain over isomeric content, water levels, unwanted byproducts, and inhibitor carryover.
Years back, most clients reached for this material with an eye to UV-curable applications or high-end polymer synthesis. We watched it move from lab-scale interest to genuine pilot plant essential as more composite manufacturers took their processes in-house. 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate finds itself going into light-activated adhesives, coatings that shrug off chemical assault, or resins with flexibility and adhesion under thermal cycling. The cyclic ether motif gives coatings both moisture protection and a tougher backbone, without the brittleness typical of straight-chain analogs.
Applications today tend to run the gamut. A lot of formulators tell us about improved weathering resistance and finer control over glass transition points in cured products. Crosslinking density becomes tunable—the structure lets network formation perform better at the micron and nanometer scale. People working in high-value electronics appreciate the material’s persistent low color and low ionic content. Dental composites and 3D-printed tooling have also found their benefits, especially in resisting hydrolysis during tough field deployments.
Some production partners prefer blending with reactive diluents. Others switch to our methacrylate entirely as a sole monomer when chasing specific flexibility profiles in copolymers. Water resistance and lower leachable content set it firmly apart from simple hydroxyethyl methacrylate or hydroxypropyl methacrylate.
The road to reliable delivery starts long before polymerization. Our approach eschews shortcuts on raw material quality. Feedstocks for the hydroxy-THF skeleton come from vetted suppliers committed to consistent, repeatable input streams. Solvent control, temperature windows, and purification steps match what we see in the tightest pharmaceutical plants—not every specialty resin customer knows it, but those measures carry forward into the handling ease, shelf stability, and final performance of the methacrylate.
Low residual acid numbers mean downstream users spend less time neutralizing reactors or policing for runaway side reactions. Years ago, early versions from others hit bottlenecks—unstable coloring, water content above spec, or inhibitor mismanagement. Our process fixes these by taking engineering and hands-on chemistry equally seriously. Every finished lot traces back through a documented quality cascade, with each checkpoint signed off by the same crew that staffed our earliest reactors.
Technicians at our plant won’t push a batch unless it passes spectroscopy for chemical fingerprints and meets chromatographic standards for purity. Each container gets checked for density, viscosity, and color index. That might sound routine, but only because we believe shortcuts on this front eventually create headaches downstream.
Some of the honest feedback comes not from datasheet reviews but from plant visits and support calls. A partner once shared how the methacrylate handled better than a competitor’s material, which seemed identical on spec sheets but caked and gelled in dosing pumps. Moisture pickup is a tough enemy in reactive monomers. Our process and packing line focus on low water introduction, right through to the final crimping of drum lids or filling of pre-set glass.
Environmental controls in our packing hall keep relative humidity tight. That means customers do not fight clumping issues in high-throughput mixer rooms. Our drums stack well, pour easily, and track via batch codes stenciled on-site.
Safety always comes up. Methacrylates have their volatility but ours responds with a very mild odor, cut sharply by careful inhibitor dosing and vacuum distillation at the right endpoint. Long shelf life and no sudden polymerization in storage keep client peace of mind intact. Storage at room temperature suits most users, and those needing extended stability at higher temperatures have reported smooth results after several months.
It’s easy for traders or distributors to focus solely on assay value or price per kilogram, but real differences play out in use. Simple hydroxyethyl or hydroxypropyl methacrylates see heavy use in commodity markets; they rarely carry through the mechanical toughness or hydrolytic resistance this cyclic variant shows. We’ve run head-to-head tests on weathering, chemical soak, and thermal exposure. The cyclic backbone shrugs off aggressive solvents and acid-base fluctuations. Crosslinked networks develop fewer microcracks and hang onto elasticity after thermal shock.
Competitive offerings often mask residual solvent or impurities through packed data tables, but their repeatability in cast films or coatings sometimes disappoints. Ours delivers an unmatched clarity in light-curing systems and remains free-flowing in piped applications for months at a time. That fluidity plays out in spray lines, printheads, and automated dispensers—speeds up every batch with less downtime or cleaning. One customer described our product as “set and forget” in their mixing line, not having to stop for filter changes or nozzle blockages.
Standard hydroxy-alkyl methacrylates bring extra water absorption; they change weight or start degrading after repeated cleaning or outdoor use. The tetrahydrofuran-based skeleton in our version sets up a molecular environment less prone to water penetration, holding gloss and mechanical grip even under wet/dry cycling.
Lower levels of leachable ions and volatiles make a difference in electronics, dental, and medical molding fields. We strictly limit metal catalysts in synthesis and steer clear of unwanted halide contamination. Downstream device reliability depends on keeping those elements out from the start—something we back up with test results for each run, examined right here by staff who know what to look for in spectral residue patterns.
Tough projects don’t always wrap on a quarterly clock. We work with resin and adhesive R&D programs that stretch across several years. Developers test blends for cure speed, network density, biocompatibility, or long-term exposure. Our track record gets tested in those cycles, with teams circling back for repeat lots in a world where few things stay consistent.
Batch-to-batch reliability wins trust over time. Spec changes, raw material swings, or shipping disruptions challenge every chemical supply chain—our shop’s veteran crew keeps a line open for early heads-up on planned runs and holds safety stock when asked. That flexibility comes from keeping internal controls at the plant, not delegating or buying blindly from outside.
Specialty projects—from coating turbine blades for energy to fabricating flexible membranes or making custom medical tools—turn to our methacrylate for certainty. Test programs rely on consistent reactivity, and researchers get the same purity and handling every time. We’ve jumped on calls for formulation tweaks and batch comparisons, giving direct answers from our process engineers without long chains of intermediaries.
Rules keep changing in every region. Methacrylates once flowed freely, then regulations tightened around emissions, volatility, and workplace exposure. We have responded with control at every emission point and document every step for traceability. Packaging gets selected with future EHS (Environmental, Health, and Safety) audits in mind—nothing winsch on cost if it could compromise quality later.
Clients from stringent markets have pushed us to lower impurity levels and verify every lot for SVHC (Substance of Very High Concern) compliance. No hidden phthalates, no risk for listed aromatic amines or persistent hazard fragments. Manufacturing shifts towards renewables or recycled content wherever possible; we tap long-term partners who commit to improving their environmental footprint.
Waste solvent and process water stay inside our loop, handled with the same accountability as finished material. Used process media undergoes distillation and recycling to limit environmental impact. Residues stay out of landfill and move strictly into proper destruction cycles.
Bottlenecks happen in specialty chemical production, often where technology moves faster than raw material supply. We invest in scalable reactors, in-line monitoring, and logistics that back up every promised kilo. Sourcing from the same feedstock suppliers year on year makes all the difference in consistency. Raw inputs sometimes see market shocks—a trend we track by pooling our buying across divisions and strong-arming reliability where needed.
Some years, global logistics threw up real hurdles. Ocean routes jammed, ports closed, and cost swings hit double digits overnight. We doubled down on local inventory, expanded storage, and staffed up in warehouse receiving. Most clients noticed we kept to delivery dates throughout ups and downs, making sure nobody got shorted.
Scaling up from pilot to full run calls out every minor impurity or thermal variation. Our engineers tinker with heat distribution, agitator speeds, and batch timing well ahead of finished stock. Small changes in pressure or feed rate ripple into product finish—regular, hands-on adjustments anchor our reputation for purity and performance.
Years of commercial supply create long ties with R&D, application engineers, and plant managers. We offer direct feedback based on what works, not simply what matches a specification. If a customer runs into curing speed problems, separation in storage, or unexpected color drift, we walk through their full process to troubleshoot from the molecular level. Quick testing, reformulation, and real feedback mark our ongoing partnerships.
Information flows two ways: plant foremen sometimes raise warnings about mixing behaviors, reactivity, or even simple drum handling. We cycle that feedback straight to production as fast as we can, cutting downtime for everyone. Our QC staff stays on call to answer questions mid-run or late at night, sometimes catching issues that automated systems miss.
Methacrylate chemistry stands at a crossroads, with both high-volume applications and precise micro-structural needs. Additive manufacturing, medical device molding, and new classes of high-performance adhesives keep stretching demands on raw materials. 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate fits the call for monomers that combine resilience, clarity, and ease of formulation.
We are observing a steady rise in end-use cases demanding custom physical properties. UV-curing leaves the lab and moves onto the production floor, so raw monomer has to tolerate storage, quick blending, and variable production rates. Our product’s backbone chemistry meets those trials without caving to hydrolysis, phase separation, or spontaneous curing.
Users stress-test our monomer in the field: wide temperature swings, humidity cycles, rough transport, or contact with solvents. The cyclic structure proves durable in long-testing protocols and intricate layer-by-layer construction, whether in dental prosthetics or industrial-grade membranes.
Some buyers underestimate the subtleties distinguishing direct-from-manufacturer material from third-party blends. Genuine control over process conditions, feedstock sources, and packing integrity shows up in warehouse receipts and lab benches. Short supply chains minimize risk of contamination or mislabeling—once material leaves our gates, it reflects everything our shop stands for.
Customers who have tried alternatives report that knockoffs or unclearly sourced lots often fail under close scrutiny. Poor thermal stability, fast yellowing, or sediment in storage can derail development programs. Keeping control at the source, with feedback loops and technical engagement, underpins our supply.
Full data support rides alongside every shipment—stripped of marketing overlays, based on real bench or plant tests. Our process documents open every step from incoming raw material to finished product. Downstream users get access to real-world numbers: chemical resistance, glass transition figures, crosslink density, and application notes derived from practice, not catalogs.
Every question, from Viscosity at set temperatures to shelf-life stability, comes answered straight by people with hands-on experience loading reactors, running columns, or pouring finished goods. We invite customers for audits, open up our lab files, and hold nothing back that might lead to process improvements for them or for us.
Working as the actual manufacturer, every day brings new context—a client’s sticky batch, a color drift, a logistics quirk. We tackle those in real-time, by phone or on-site, coordinating tweaks and shipping out tweaks or replacements when called for. There is no filter in communication; solutions move fast.
Users who want more than just a commodity transaction find value in our approach. Tracking real-time supply status, tweaking formulations to pair with new equipment, or customizing inhibitor doses suit buyers seeking thorough answers, not silent containers. Our approach grows from decades of direct industry pressure—not from reselling, not from buying spot market, but from building reliable product with sweat and judgment at every turn.
Making 3-Hydroxy-2-Methyltetrahydrofuran Methacrylate at 99% purity brings together decades of technical experience, hard-won plant insight, and a direct line to every batch that leaves the site. Its unique cyclic backbone and methacrylate group enable users to create advanced coatings, adhesives, composite resins, and specialty polymers with confidence that every drum matches the one before.
The product’s physical and chemical steadiness flows from manufacturing rigor—every process step, every supply partnership, every warehouse policy gets shaped by the needs of demanding industries. When new challenges arise, whether driven by regulation, environment, or untested application, we stand ready as the direct source: offering reliable product, informed answers, and hands-on support that enable opportunities in chemistry to become realities on the shop floor.
