The journey of MVAF-T5 resin traces back to the early research on functionalized polyvinyl chloride in the 20th century, when chemists wanted something more versatile than standard commercial PVC. Adding vinyl acetate to the backbone and then introducing hydroxyl groups, researchers managed to carve out a niche material. The world faced vast demand for more reliable coatings and inks, pushing companies to develop copolymers with improved adhesion and stability. As industries moved into the 1970s and 1980s, surface chemistry and application-specific polymers grabbed everyone’s attention. I remember flipping through old technical manuals from those decades, seeing the first references to hydroxyl-modified vinyl copolymers as “next-generation” materials for high-end paints and protective formulations. These were days when innovation felt tangible, and real-world needs drove chemistry forward.
MVAF-T5 resin stands out with a blend of vinyl chloride and vinyl acetate monomers, further tweaked with hydroxyl functionality. This particular adjustment gives the resin a unique set of benefits, especially for formulators hunting for good adhesion and chemically reactive sites. In the lab, the pale-white or slightly yellow granules give away their readiness to dissolve in common solvents like ketones and esters. The resin doesn’t just fill a gap between two categories—PVC and PVA—it's the answer for those needing paint and ink binders that bond both to the substrate and to crosslinkers. In paints, lacquers, and gravure inks, this copolymer helps deliver toughness and resistance where ordinary resins crumble. Years ago, I worked alongside a coatings chemist who swore by this exact type of copolymer for hard-wearing traffic paints, praising its unique “stick and seal” approach.
Looking at MVAF-T5 resin under a microscope doesn’t reveal much, but processing it tells another story. This material typically appears as a fine powder, sometimes coarse granules. It easily dissolves in methyl ethyl ketone or cyclohexanone, a handy trait for paint makers. The critical hydroxyl group content—usually somewhere between 1.5% and 3.5% by weight—lets formulators design chemical cross-links or blend with isocyanate agents. The softening point usually ranges from 90°C to 105°C, depending on the amount of vinyl acetate, landing it in that sweet spot for application by roller or spray. The copolymer offers a glass transition temperature (Tg) close to standard PVC, but a bit lowered because of the acetate chunks, so it handles thermal expansion better. Water doesn't faze this resin much, and it shrugs off UV rays when tested outdoors, which becomes crucial in protective topcoats or marine finishes.
MVAF-T5 isn’t just a name; suppliers assign grades based on hydroxyl values, viscosity in solvent, and degree of polymerization. Roll up your sleeves and check the datasheets—viscosities (in a standard 20% MEK solution) might land between 7-20 mPa.s. Suppliers often specify hydroxyl content, bulk density, volatile residue, and filtration particle size. Labels should absolutely state the batch number for traceability, storage recommendations, and shelf life (often two years if kept cool and dry). These details matter not just for regulation, but for anyone running a tight ship in manufacturing. Once, a mislabeled batch of resin forced a refit in a European packaging plant, bringing home to me the importance of clear, consistent labeling and genuine batch records for industrial peace of mind.
Manufacturing MVAF-T5 usually demands suspension or emulsion polymerization. In practice, producers combine vinyl chloride and vinyl acetate monomers in the presence of a radical initiator and a suspension agent. Working as a junior process engineer, I watched reactors run for hours on end, their temperature tightly controlled. The magic comes with a post-polymerization grafting or copolymerization step, where hydrolyzed vinyl acetate or a special hydroxyl-containing monomer is introduced. Filtration and drying follow, with anti-caking agents making transport and storage easier. The seasoned operator swears by small tweaks—initiator level, mixing speed, or addition order—to boost consistency and keep the product within spec.
The real usefulness of MVAF-T5 resin comes out when those hydroxyl groups start reacting. In two-component systems (think industrial floor coatings), isocyanates latch onto those hydroxyl hooks, creating tough, chemical-resistant networks. In adhesives, formulators sometimes graft on silanes or blend in epoxy oligomers to push the performance window even further. In my own experience mixing formulations, blending this type of resin with other copolymers expanded the toolbox—one could tune flexibility, block water uptake, or even improve printability with simple formulation tweaks. There's almost no end to creative chemistry once you've got a reactive backbone.
The industry isn’t shy about giving every resin a few aliases. On a product shelf or a chemical order, MVAF-T5 might come up as “hydroxylated vinyl copolymer,” “hydroxyl-functional PVC-VA copolymer,” or a proprietary trade name from paint giants in Japan or Germany. The same chemistry might hide behind codes like VROH or specific company numbers. Reading patent literature or comparing international safety documents can leave you wading through acronyms, but at the core it’s all about a vinyl chloride and vinyl acetate blend with built-in hydroxyls.
Every time someone handles vinyl chloride materials, safety steps up as the top priority. Plant operators receive training not just in respirator use, but in careful dust management—fine powders like MVAF-T5 disperse easily and can produce localized dust. Vinyl chloride, as every regulatory body warns, brings carcinogenic risks, so closed systems and active ventilation go beyond “nice-to-have.” Finished resin itself doesn’t carry the same hazard, but shipping documents, SDS, and emergency response kits form a strict part of daily safety culture. Gloves, goggles, and proper clothing aren’t just recommendations, they’re non-negotiable. Regular air monitoring, either in production or downstream blending, ensures nobody misses hidden volatility in processing rooms. Years ago, I toured an Asian ink plant where engineering controls and hands-on chemical safety audits went hand in glove—without that, no one would sign off on releasing batches for the food packaging sector.
Industry after industry leans on MVAF-T5 resin when reliable performance is needed. Packaging inks rely on it for lamination bonds that face boiling and deep freezing cycles. Road paints and deck coatings benefit from its mix of stickiness and backbone; graffiti washes right off, while UV rays barely leave a mark. Electrical cable jackets and insulation tapes use it for mechanical strength, a clever trick that keeps cables flexible in the field. Even flexible films, artificial leather coatings, and release liners for stickers make good use of the adhesion and film-forming traits baked into the copolymer. From the time I consulted for a small print shop, I saw this resin unlock more vibrant colors and longer print runs—proof-positive that materials science lands squarely in daily life.
Recent years have witnessed R&D focusing on optimizing the balance between performance and cost for MVAF-T5 resin. Labs push for versions compatible with waterborne systems, aiming to balance solubility and low-VOC (volatile organic compound) regulations. Scientists in Europe and Asia wrestle with biopolymer compatibilization, where MVAF backbones meet plant-derived plasticizers or renewable fillers. I keep an eye on academic literature, where cross-linking efficiency and aging tests pack into dozens of papers each quarter. Partnerships between chemical companies and downstream formulators help bridge gaps, as seen in new lines of eco-friendly automotive paints and recyclable packaging. Open-source research models or patent pools could further democratize innovation, letting even small labs test tweaks on existing polymer frameworks. That kind of collaboration moves discovery faster than chasing proprietary secrets.
The health impacts of vinyl chloride monomer linger in chemical history books, and the industry faces continued scrutiny over the whole family of resins. Finished MVAF-T5 resin, after polymerization, contains little to no free monomer, minimizing immediate toxicity risks if handled according to standards. Chronic exposure guidelines remain in place, but recent toxicology studies show that workers exposed only to processed, finished powder avoid the worst risks. Still, regulators frown on complacency. Some research hints that additives (plasticizers, stabilizers, or pigments) might migrate if the formulation isn’t done right. Continuous animal studies, tissue absorption analyses, and workplace air quality monitoring form the backbone of chemical safety. Relying only on historical toxicity tables doesn’t cut it; companies must regularly review new data from global partners. My contacts in environmental health stress the importance of transparency—traceability from monomer tank to packaged paint builds trust with safety inspectors and the public.
Looking ahead, MVAF-T5 faces the double-edged sword of rising demand and tightening regulation. Construction, transportation, and packaging industries want ever-better protective and decorative coatings, while regulators press for lower emissions and safer workplaces. Bioplastic compatibilization and hybrid materials could give this old workhorse new life, especially as the world turns its back on petrochemicals. Smart coatings with embedded conductivity, self-healing networks, or enhanced antimicrobial features may spring from the same chemical skeleton if R&D minds tackle the challenge. Cooperation across continents, continued investment in workplace safety, and commitment to low-migration additives would keep MVAF-T5 relevant even as alternative chemistries gain ground. The need for resilient, durable, and customizable polymers won’t go away, and those prepared to innovate will find no shortage of challenges or opportunities.
Most folks don’t think much about what keeps paint sticking to metal fences or protects the outside of buildings from peeling in the rain. MVAF-T5 resin, a hydroxyl-modified vinyl chloride/vinyl acetate copolymer, turns out to be one of the unsung heroes in these products. This resin gives paints and industrial coatings tough bonding power, making weathered surfaces last longer before signs of rust or decay set in. Take bridges, for example. Their regular battles against sun and salty air would win a lot more often if not for coatings built around resilient resins. Combining solid adhesion with resistance to water and chemicals, MVAF-T5 helps maintenance crews and city budgets by slowing down the endless cycle of repainting and repair.
Opening a box of cereal, you expect those bright colors on the packaging to stay crisp—no smudging, no fading. MVAF-T5 resin forms a reliable base for inks, locking in pigments and keeping print sharp on all sorts of surfaces, even plastics and tricky metallic films. Flexographic and gravure printers lean on this dependable resin to deliver clean graphics for everything from snack wrappers to labels on medical supplies. The real value shows up on store shelves and in food processing, where even small slip-ups in ink performance can cause spoilage, regulatory headaches, or recalls.
Try gluing PVC to metal or glass, and cheap adhesives fail fast. MVAF-T5 resin helps manufacturers build adhesives with real sticking power, harnessing its chemical compatibility with both organic and inorganic materials. In the automotive industry, these adhesives cut down on mechanical fasteners and welds, which rattle or rust over time. For electronics assembly, the resin’s stability keeps devices together in harsh heat and humidity. These are the little victories that keep dashboards solid and smartphones in one piece.
Shoppers see smooth, clear plastic on everything from credit cards to medicine packets. MVAF-T5 resin lets film and sheet makers craft products that balance flexibility with some serious tear resistance. It resists stretching out of shape, so laminated ID cards endure years of handling. Pillow packs and pharmaceutical blisters hold up on shipping trucks without splitting or curling. These small acts—cards lasting, medicine staying sterile—each trace back to thoughtful use of the right polymer chemistry.
MVAF-T5 resin gets plenty of requests from fields like textiles, where it helps with waterproof coatings on outdoor gear. Nail polish? The resin ensures chips don’t show up on day two. Architecturals rely on its weather-shielding in wall coverings and decorative laminates. I’ve tinkered with some of these materials myself. Vinyl-based polymers helped keep an outdoor sign legible through seasons of rain and sun that usually turn painted surfaces into flaky messes.
Raw materials in the chemical industry, including MVAF-T5 resin, play a real role in things that touch daily life: safety, longevity, waste reduction. Nearly all of us benefit from coatings that hold up, inks that don’t contaminate food, or adhesives that protect delicate electronics. MVAF-T5 doesn’t just live inside factories; it works out in the open, saving resources, keeping surfaces safe, and reducing both hassle and cost for industries and consumers alike.
Talk to anyone in the chemical or manufacturing trades, and you’ll hear that materials matter. MVAF-T5 resin grabs attention, not just because of its chemistry, but for what it does across different settings. This isn’t a newcomer that’s just about flexibility; it often finds a place in stories about performance, stability, and safety.
Polymer resins have a reputation for being choosy about heat. I’ve handled enough materials over the years to know that the slightest tweak in temperature can lead to issues. MVAF-T5 resin earns its stripes in the lab and on the factory floor for holding up at higher temperatures. That’s critical for making parts that aren’t supposed to warp, crumble, or even release harmful compounds in tough production cycles. Some technical data shows MVAF-T5 comfortably withstands temperatures that would defeat typical resins, and in my own work, I’ve seen it used in electronic assemblies right next to heat-generating components.
So much of finished goods manufacturing boils down to mechanical properties. I’ve been in shops where resins cracked under pressure, forcing production shutdowns and a scramble for better alternatives. MVAF-T5 brings a certain toughness—think resistance to cracking, chipping, and abrasion—that gives engineers confidence. Toughness alone doesn’t sell a product; it’s the combination of strength and the way the material can bend and flex slightly under stress. The numbers don’t lie: Published stress-strain data suggest MVAF-T5 holds its shape under load, outperforming more brittle cousins.
There’s little worse than watching a material degrade from chemical exposure. In the coatings trade, and especially in environments heavy with solvents or acids, the right resin makes all the difference. I’ve seen MVAF-T5 specified in paint formulations and protective coatings because it doesn’t give up easily when exposed to aggressive chemicals. Beyond anecdote, corrosion testing and chemical soak analyses confirm that MVAF-T5 shields what’s underneath, saving businesses from costly reapplications.
One of the first checks with resin systems is whether they bond to common surfaces. MVAF-T5 excels at sticking to metals, plastics, and composites, but also releases easily from molds when needed. I remember collaborating with a composites fabricator who switched to MVAF-T5 for its reliable curing and minimal post-process cleanup. Productivity shot up. Processing flexibility—like short cure times, compatibility with different hardeners, and even reduced volatility—reduces headaches on the production floor.
These days, concerns about workplace exposure and environmental release shape buying decisions. MVAF-T5 typically registers as low in harmful emissions. Reports from industrial hygiene teams back this up with consistent test results. Less outgassing means safer air quality for workers and makes compliance with tightening rules far more manageable. I’ve worked with resin systems flagged for volatile organic compounds, and it’s clear that families of resin like MVAF-T5, which sidestep a lot of these problems, get picked more often by responsible shops.
No material is perfect. MVAF-T5 costs more upfront than basic resins, which puts budgets under stress for high-volume jobs. Some companies counter this by adopting a hybrid approach—using MVAF-T5 only in high-risk zones while relying on standard resin elsewhere. Further research could focus on bringing down manufacturing costs without losing the prized stability or strength. Material scientists experiment with fillers or recycling post-consumer resin, which might help.
Anyone who has spent time working with specialty resins knows small decisions in storage can make or break both safety and product performance. MVAF-T5 Resin, like so many specialty chemicals, calls for a steady approach to storage. It doesn’t thrive in the chaos of a cluttered shelf or sit quietly in a garage next to a lawnmower. Even if you’re handling just a few kilograms, some habits stick for good reason.
Keep MVAF-T5 Resin in a dry, cool, and well-ventilated space. I learned early on not to ignore temperature swings—these play a big part in how long a resin keeps its quality. Aim for steady temperatures, ideally below 25°C. Humidity can sneak moisture into even sealed bags; once that happens, clumping, changes in flow, and possible reactions follow. Use desiccants for extra peace of mind. Every facility I’ve worked in keeps resins off the floor—wooden pallets give space for ventilation and keep things clean. Nobody enjoys scraping up a sticky mess from a resin that’s absorbed a spill or humidity.
MVAF-T5 Resin belongs far from open flames or sources of high heat. Keeping it away from sunlight is an obvious step, but don’t forget about hot machinery nearby or even warehouse walls baking in the summer sun. Original packaging protects for a reason. If the bag or drum takes damage, reseal or transfer carefully. Leaving containers open encourages dust, debris, or insects to creep in. Every warehouse worker learns quickly: closed and labeled keeps surprises away.
It’s tempting to skimp on personal protection, especially on busy days. Still, gloves, goggles, and long sleeves keep resin dust off your skin and out of sensitive areas. Accidental contact rarely leads to disaster, but irritation and allergies set in over time. Respirators or dust masks aren’t overkill either, given the fine powders involved.
MVAF-T5 releases fine dust if mishandled during pouring or mixing. Good local exhaust ventilation prevents airborne dust. In one project, we relied on dust collectors during every transfer—paying attention to dust control cut cleanup times and avoided health complaints. Spills invite slip hazards and cleanup headaches. Use a vacuum cleaner with HEPA filtration, not brooms or compressed air, to collect resin. Sweeping just spreads material around, raising the chance someone will track it to clean areas.
Simple recordkeeping also pays off. Track each delivery, log every time a drum gets opened, and monitor usage rates. This, plus clear batch labeling, supports any quality control tracebacks. If anything goes off-spec, quick backtracking can isolate problems. In my experience, a whiteboard by the storage rack—a low-tech trick—works wonders for team communication.
Supply chains move quickly, but storage rules often get ignored in the scramble. A solid solution involves training staff to respect handling procedures. Spot checks and regular safety briefings foster good habits. Clear signage beats long-winded manuals—they remind even the most seasoned staff where and how to store MVAF-T5 safely.
Waste management deserves attention. Large resin spills or expired material need disposal as per environmental guidelines, not down the nearest drain. Partnering with a reliable hazardous waste service avoids run-ins with regulators. Over time, these systems create less waste and more consistency—something every operation can appreciate.
Good storage and handling keep both people safe and MVAF-T5 Resin at its best. Rushed decisions or shortcuts only add risk. Attention to detail rewards everyone with a smoother workflow and a more reliable product down the line.
MVAF-T5 resin plays a growing role in paints, adhesives, lacquers, and coatings. Getting the most out of it means giving careful attention to the solvents you partner with it. The wrong decision can gum up machinery, stall projects, leave a poor finish, or introduce hazards into a working environment. The right pick helps keep product quality high and safety concerns under control. Having worked with specialty polymers, I have seen teams save both time and resources just by knowing which solvents will actually deliver reliable results with a resin like MVAF-T5.
MVAF-T5 shows solid compatibility with several tried-and-tested solvents, usually ones considered as “weak” or “mid-strength” solvents for resins. Toluene is often a reliable workhorse—fast action, reasonable cost, and consistent resin solubility make it a mainstay in many production settings. Xylene comes up nearly as often, helping with situations that need a slightly slower evaporation rate or when formulators want flexibility in blend ratios. Solvent naphtha (aromatic) works for those looking for a middle ground between rapid and drawn-out drying times.
Pure alcohols—such as isopropyl alcohol and ethanol—blend with MVAF-T5 but show more limited carrying capacity; you usually see them as secondary components, not the main ingredient, especially when clarity or fast drying is critical. Acetone, despite its strength, sometimes gets used for quick spot treatments in lab settings, though it’s not always recommended for industrial blends due to the possibility of softening or yellowing. For greener chemistry, “eco-solvents” like ethyl lactate can dissolve MVAF-T5, but the cost and odor sometimes push folks back to the aromatic hydrocarbon group. Cyclohexanone and MEK (methyl ethyl ketone) both perform well in small batch work if users watch for volatility and safety constraints.
Not all “universal” solvents play nice with MVAF-T5. Water, for all its appeal, doesn’t work unless the resin comes pretreated or designed for water dispersibility. Aliphatic hydrocarbons (like hexane or mineral spirits) tend to show low solubility; mixing usually yields cloudy messes or lumps, even at higher temperatures. Chlorinated solvents—while powerful—raise red flags for health and disposal, rarely worth the risk with so many better alternatives on the table. I’ve also seen issues crop up with strong polar solvents like dimethyl sulfoxide (DMSO) or dimethylformamide (DMF); often they create uneven films or disrupt consistency.
Anyone working with MVAF-T5 should demand proper safety equipment and ventilation—solvent exposure adds up, even in short tasks. Local laws shape what ends up being practical; some states restrict specific aromatics, forcing users toward lower-impact choices. Customers are starting to ask more questions about residues, odor, and environmental impact; switching to lower VOC (volatile organic compound) blends and reclaimable solvents now often brings business advantages along with health benefits. Manufacturers can help guide end users with clearer documentation about which solvents deliver full performance, and share data from testing in real-world conditions, not just under lab glass.
The best step any facility can take is to run a small-scale compatibility test under the same temperature, humidity, and equipment conditions used in production. Field experience says direct contact between the resin and alternatives like esters or green solvents is crucial, and not to rely only on technical datasheets. For better process control, mixing solvents—using aromatic for base solubility, then a bit of alcohol or ether for fine-tuning flow and dry time—can make finished products more predictable and easier to apply. Reaching out to resin suppliers for current solvent recommendations has saved project leads in my experience from expensive rework or late-stage performance failures.
Anyone who's been around manufacturing knows the topic of material safety can’t be brushed aside, especially when eating utensils or medical syringes touch those surfaces. Parents don’t want toxins leaching into meals, and no one looks forward to a hospital stay made riskier by cheap materials. Folks trust standards because it’s nearly impossible to tell at home if a spoon is hazardous just by looking at it.
MVAF-T5 resin has appeared in product specs across industries, from plastic components to packaging. But trust doesn’t come just from an impressive chemical label. The key questions always circle back to food-contact and health-based approvals. According to government agencies like the FDA and organizations such as EFSA, only certain plastics earn a green light. The specifics depend less on the brand name and more on what chemicals might escape the final product.
Looking at the technical sheets, MVAF-T5 falls under thermoplastics, potentially similar to certain grades of vinyl acetate or related copolymers. Getting from a raw chemical to a safe-for-use container means the resin doesn’t just need good strength or durability. What matters most: Will that resin break down, dissolve, or shed molecules when heated, microwaved, or sitting in acidic foods? The resin must not release anything harmful—no small feat, considering the range of chemicals possible in many plastics.
No regulatory authority like the FDA, European FCM standards, or USP has approved MVAF-T5 resin for direct food contact or medical use as of June 2024. The authorities keep a public database listing approved substances, and MVAF-T5 sits outside those lists. If a manufacturer claims food or medical safety, they must provide third-party lab documentation showing migration studies, toxicological assessments, and proof that the resin passes extraction and leaching tests.
These regulatory steps require more than a certificate from the supplier. Food safety is a public trust issue. In a world where microplastics, BPA, and phthalates already prompt recalls, nobody wants another headline about unexpected chemical exposure. Businesses choosing MVAF-T5 resin need to back up claims, not just for compliance, but for the health of the people using these products.
Shortcuts in safety testing don’t just bring fines. They risk company reputations and invite lawsuits. On the consumer side, food containers made from untested resins threaten health, especially for vulnerable groups like children and patients with compromised immune systems. Even trace migration of unwanted chemicals has been linked to chronic illnesses and hormone disruption. I’ve seen brands lose years of consumer trust over single incidents that could have been prevented with thorough vetting.
Manufacturers planning to use MVAF-T5 in food or medical applications should perform a full audit of the supply chain. They should demand transparent safety data from suppliers, push for accredited third-party lab results, and conduct in-house migration tests. Documentation must match global standards. Some companies have even started publishing these test results to regain and keep customer trust.
No resin is “probably fine”—it’s either proven safe or not. The safest products on the market earn that title with hard evidence, not assumptions. If MVAF-T5 resin one day appears on the FDA or EFSA approved lists, it’ll only be after passing the gauntlet of safety checks that buyers expect.
| Names | |
| Preferred IUPAC name | hydroxy-modified poly(chloroethene-co-ethenyl acetate) |
| Other names |
Denka MVAF-T5
Denka Vinyl Resin MVAF-T5 |
| Pronunciation | /ˌɛm.viː.eɪˈɛf ˈtiː.faɪv ˈrɛz.ɪn/ |
| Identifiers | |
| CAS Number | 25035-98-7 |
| Beilstein Reference | 3858734 |
| ChEBI | CHEBI:53288 |
| ChEMBL | CHEMBL2107828 |
| DrugBank | DB13919 |
| ECHA InfoCard | 13bb3559-5f7e-49f2-b2f4-f709ffb5d045 |
| EC Number | EC 500-013-7 |
| Gmelin Reference | 66421 |
| KEGG | C19773 |
| MeSH | Polyvinyl Chloride |
| PubChem CID | 135349425 |
| RTECS number | QJ6950000 |
| UNII | 5W8CT4EE96 |
| UN number | UN1866 |
| CompTox Dashboard (EPA) | DTXSID2012875 |
| Properties | |
| Chemical formula | (C2H3Cl)m·(C4H6O2)n·(C2H4O)x |
| Molar mass | 76,000–99,000 g/mol |
| Appearance | White powder |
| Odor | Faint characteristic odor |
| Density | 0.36 – 0.42 g/cm³ |
| Solubility in water | Insoluble |
| log P | -0.94 |
| Acidity (pKa) | 12.5 (calculated) |
| Basicity (pKb) | 10.15 |
| Refractive index (nD) | 1.510 |
| Viscosity | 260-520 cps |
| Dipole moment | 1.77 D |
| Pharmacology | |
| ATC code | Not assigned |
| Hazards | |
| GHS labelling | GHS labelling: "Warning; H315, H319, H335; P261, P264, P271, P280, P302+P352, P305+P351+P338, P312, P332+P313, P337+P313, P362+P364 |
| Pictograms | GHS07,GHS09 |
| Signal word | Warning |
| Hazard statements | H226, H319, H335 |
| Precautionary statements | P264, P280, P301+P312, P305+P351+P338, P337+P313 |
| Flash point | > 14°C |
| Autoignition temperature | 400°C |
| LD50 (median dose) | LD50 (median dose): >5000 mg/kg (Rat, Oral) |
| NIOSH | GLJ020000 |
| REL (Recommended) | 9-13% |
| Related compounds | |
| Related compounds |
Vinyl Chloride/Vinyl Acetate Copolymer
Hydroxyl-Modified Vinyl Chloride Copolymer MVAF-T6 Resin VAGH Resin Vinyl Acetate Homopolymer Polyvinyl Chloride (PVC) |
