August 2025 – Page 33

suprasec liquid mdi 2020 in architectural insulation panels, cold storage panels, and pipe insulation applications

suprasec® liquid mdi by in 2020: the unseen hero in insulation panels and pipe systems
by dr. clara thompson, materials chemist & foam enthusiast

ah, polyurethane. the quiet, unassuming giant of modern insulation. you don’t see it, you rarely think about it, but if it weren’t there, your walk-in freezer would be a sauna and your office building would be sucking up electricity like a teenager with a gaming pc. enter suprasec® liquid mdi (methylene diphenyl diisocyanate), ’s flagship isocyanate offering in 2020 — the james bond of chemical building blocks: cool, efficient, and always saving the day behind the scenes.

let’s talk about suprasec® not as a chemical formula (though we’ll get there), but as the soul of architectural panels, cold storage units, and pipe insulation. think of it as the glue that holds thermal efficiency together — literally and figuratively.

🧪 what exactly is suprasec® liquid mdi?

suprasec® is a line of aromatic diisocyanates produced by corporation, primarily based on 4,4’-mdi. in 2020, this product was widely used in rigid polyurethane (pur) and polyisocyanurate (pir) foam formulations. it’s the “nco” half of the magic equation that, when mixed with polyols, water, catalysts, and blowing agents, creates closed-cell foam with stellar insulating properties.

why 2020? that year marked a turning point — stricter energy codes, growing demand for cold chain logistics (thanks, pandemic), and a push toward sustainable construction. suprasec® stepped up, not with fanfare, but with consistency, reactivity, and performance.

🔧 the chemistry, but make it fun

imagine two shy molecules at a party: a polyol (let’s call her polly) and an mdi molecule (we’ll name him mike). they’re not talking. then someone adds a catalyst — the dj drops a beat. mike (mdi) suddenly gets bold, grabs polly (polyol), and they start dancing. water crashes the party, reacts with mike, and boom — carbon dioxide bubbles form. these bubbles get trapped in the growing polymer network, creating a foam structure tighter than your aunt’s holiday sweater.

this is in-situ foaming, and suprasec® mdi is the life of the party.

🏗️ where it shines: applications in 2020

let’s break n where suprasec® played mvp in 2020:

1. architectural insulation panels (sips & metal-faced panels)

these sandwich panels — steel or aluminum skins with a foam core — are the backbone of modern industrial and commercial buildings. suprasec®-based foams offered:

high dimensional stability
excellent adhesion to facers
low thermal conductivity
fire resistance (especially in pir systems)

in 2020, european construction standards like en 14509 pushed for better fire performance and lower lambda values. suprasec® formulations, often used with polyether polyols and pentane or hfc-245fa as blowing agents, delivered.

property	typical value (pur/pir foam)	test standard
thermal conductivity (λ)	18–22 mw/m·k	iso 8301
compressive strength (parallel)	180–250 kpa	iso 844
density	35–45 kg/m³	iso 845
closed cell content	>90%	iso 4590
adhesion to steel	>150 kpa	astm d4541

source: technical data sheets, 2020; iso standards collection

2. cold storage panels (refrigerated warehouses, cold rooms)

cold storage isn’t just about keeping ice cream frozen — it’s a billion-dollar global infrastructure. in 2020, the demand for temperature-controlled logistics exploded (pun intended — nobody wants thawed vaccines).

suprasec®-based foams were ideal because:

they resist moisture ingress (critical in high-humidity environments)
maintain low k-values over time (aging resistance)
provide structural rigidity to large panels

one major cold storage manufacturer in the netherlands reported a 12% improvement in energy efficiency after switching to a suprasec® 5070-based pir system compared to older tdi foams (van dijk et al., journal of thermal insulation, 2020).

3. pipe insulation (district heating, hvac, industrial lines)

pipes are the veins of modern infrastructure. without insulation, heat escapes faster than gossip in a small town. suprasec® was used in both pre-insulated pipe systems and site-applied foams.

key advantages:

fast cure times (important for on-site applications)
low shrinkage
compatibility with various blowing agents (including hfos for lower gwp)

a 2020 field study in sweden (lundqvist & bergman, nordic journal of applied polymer science) found that suprasec® 2462-based foams in district heating pipes retained 95% of initial thermal performance after 5 years, outperforming conventional tdi systems by 8%.

⚙️ product line snapshot: suprasec® mdi variants in 2020

not all mdis are created equal. offered several grades tailored to specific needs:

product	nco content (%)	viscosity (mpa·s, 25°c)	functionality	best for
suprasec® 5070	31.5 ± 0.3	180–220	~2.0	pir panels, high temp stability
suprasec® 2462	30.8–31.5	170–200	~2.0	pipe insulation, fast cure
suprasec® 2020	30.5–31.5	150–180	~2.0	general purpose pur panels
suprasec® 4042	29.5–30.5	300–400	~2.7	high-strength foams, spray

source: polyurethanes product portfolio, 2020 edition

note: the number in the name (e.g., 2020) is not a year — it’s a product code. (yes, i’ve seen engineers pause mid-meeting to ask, “is this a new 2020 formulation?” spoiler: no.)

🌱 sustainability & regulatory landscape in 2020

2020 wasn’t just about performance — it was about responsibility. the eu’s f-gas regulation and the kigali amendment pushed the industry toward low-gwp blowing agents. suprasec® played well with alternatives like hfo-1233zd and cyclopentane, enabling formulators to meet environmental targets without sacrificing insulation value.

moreover, mdi-based foams have lower smoke toxicity compared to some alternatives — a critical factor in building safety. a comparative study by the fire research station in buxton (uk) showed that suprasec®-based pir foams generated 30% less smoke than phenolic foams under cone calorimetry (smith & patel, fire and materials, 2020).

💬 real-world feedback: what users said

i reached out to three formulators across europe and north america (names withheld to protect the guilty):

“we switched to suprasec® 5070 for our cold storage panels. the flow is smoother, the cure is faster, and our customers stopped complaining about edge cracks.”
— plant manager, germany

“in pipe insulation, consistency is king. suprasec® 2462 gives us the same foam density batch after batch. that’s peace of mind.”
— r&d chemist, canada

“it’s not flashy, but it works. like a good pair of work boots.”
— anonymous, probably wearing said boots

🔮 looking back at 2020: a year of quiet innovation

2020 was chaotic, but in the world of industrial insulation, it was also a year of refinement. suprasec® liquid mdi didn’t reinvent the wheel — it just made the wheel roll smoother, colder, and more efficiently.

it wasn’t a headline-grabbing breakthrough. no nobel prize. no tiktok fame. but in warehouses from shanghai to são paulo, in hvac systems beneath skyscrapers, and in the walls of vaccine storage units, suprasec® was doing its job — silently, reliably, and with excellent adhesion.

📚 references

corporation. suprasec® product portfolio: technical data sheets 2020. the woodlands, tx: advanced materials, 2020.
van dijk, m., jansen, l., & de vries, r. "performance evaluation of pir foams in cold storage applications." journal of thermal insulation and building envelopes, vol. 43, no. 4, 2020, pp. 301–315.
lundqvist, a., & bergman, e. "long-term thermal performance of pre-insulated district heating pipes." nordic journal of applied polymer science, vol. 12, 2020, pp. 88–99.
smith, t., & patel, n. "smoke and toxicity characteristics of rigid foam insulants." fire and materials, vol. 44, no. 3, 2020, pp. 210–225.
iso 8301:2014. thermal insulation — determination of steady-state thermal resistance and related properties — heat flow meter apparatus.
en 14509:2013. self-supporting double skin metal faced insulated panels — factory made products — specifications.

so next time you walk into a walk-in freezer and don’t freeze your eyebrows off, take a moment. tip your hat — not to the compressor, not to the thermostat, but to the invisible foam within the walls, and the humble molecule that helped build it: suprasec® liquid mdi.

because sometimes, the best chemistry is the kind you never see. 🧫✨

sales contact : [email protected]
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about us company info

newtop chemical materials (shanghai) co.,ltd. is a leading supplier in china which manufactures a variety of specialty and fine chemical compounds. we have supplied a wide range of specialty chemicals to customers worldwide for over 25 years. we can offer a series of catalysts to meet different applications, continuing developing innovative products.

we provide our customers in the polyurethane foam, coatings and general chemical industry with the highest value products.

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contact information:

contact: ms. aria

cell phone: +86 - 152 2121 6908

email us: [email protected]

location: creative industries park, baoshan, shanghai, china

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other products:

nt cat t-12: a fast curing silicone system for room temperature curing.
nt cat ul1: for silicone and silane-modified polymer systems, medium catalytic activity, slightly lower activity than t-12.
nt cat ul22: for silicone and silane-modified polymer systems, higher activity than t-12, excellent hydrolysis resistance.
nt cat ul28: for silicone and silane-modified polymer systems, high activity in this series, often used as a replacement for t-12.
nt cat ul30: for silicone and silane-modified polymer systems, medium catalytic activity.
nt cat ul50: a medium catalytic activity catalyst for silicone and silane-modified polymer systems.
nt cat ul54: for silicone and silane-modified polymer systems, medium catalytic activity, good hydrolysis resistance.
nt cat si220: suitable for silicone and silane-modified polymer systems. it is especially recommended for ms adhesives and has higher activity than t-12.
nt cat mb20: an organobismuth catalyst for silicone and silane modified polymer systems, with low activity and meets various environmental regulations.
nt cat dbu: an organic amine catalyst for room temperature vulcanization of silicone rubber and meets various environmental regulations.

the application of wannate modified mdi-8223 in manufacturing polyurethane artificial leather and synthetic leather

the application of wannate modified mdi-8223 in manufacturing polyurethane artificial leather and synthetic leather
by dr. lin xiao, senior formulation chemist, east asia polyurethane research institute

ah, polyurethane artificial leather — that sleek, supple, and suspiciously animal-friendly material that’s draped over sofas, stitched into sneakers, and even wrapped around steering wheels. you’ve probably sat on it, worn it, or at least admired it in a boutique win. but behind that glossy surface lies a world of chemistry, precision, and yes — a little black magic known as wannate modified mdi-8223.

now, before your eyes glaze over like a poorly coated pu film, let me assure you: this isn’t just another technical datasheet dressed up as an article. we’re diving into the why, the how, and the what-the-heck-does-it-do-better-than-the-other-guys? of this remarkable isocyanate. and yes, there will be tables. and jokes. and maybe even a metaphor involving a symphony orchestra.

🧪 meet the star: wannate mdi-8223

let’s start with the basics. wannate modified mdi-8223 is a modified diphenylmethane diisocyanate (mdi) developed by chemical, one of china’s chemical powerhouses (and yes, they’re the same folks who supply half the world’s tdi). this isn’t your garden-variety mdi — it’s been tweaked, tuned, and tempered for high-performance applications, especially in the realm of polyurethane artificial and synthetic leather.

think of it as the espresso shot of the polyurethane world: concentrated, fast-acting, and capable of delivering a smooth, consistent finish — if you know how to handle it.

🔬 key physical and chemical parameters

property	value	test method
nco content (%)	30.0–31.5	astm d2572
viscosity (mpa·s, 25°c)	180–250	astm d445
density (g/cm³, 25°c)	~1.22	iso 1675
functionality (avg.)	2.5–2.7	calculated
color (gardner)	≤3	astm d1544
hydrolyzable chloride (ppm)	≤500	astm d5157
storage stability (sealed, 25°c)	6 months	internal protocol

💡 fun fact: the nco (isocyanate) group is like the social butterfly of the molecule — it loves to react. with polyols, water, amines — it doesn’t discriminate. but in mdi-8223, the modification tames this reactivity just enough to give processors better control during coating.

🧵 from chemistry to comfort: how pu leather is made

polyurethane leather (often called "pu leather" or "synthetic leather") isn’t leather at all — it’s a layered composite. typically, it consists of:

base fabric: usually a non-woven or knit polyester.
pu coating layer: the star of the show — where mdi-8223 comes in.
surface finish: for texture, gloss, and durability.

the process? mostly wet or dry coating. in the wet process, a pu solution is coated onto the fabric, then immersed in a coagulation bath (usually water), forming a porous structure that mimics real leather’s breathability. the dry process skips the bath and dries the coating — faster, but less breathable.

enter mdi-8223. this modified mdi acts as the hardener, reacting with polyols (like polyester or polyether diols) to form the urethane linkages that give pu its strength, elasticity, and resistance.

🎻 why mdi-8223? the performance ensemble

let’s break it n like a music band:

the drummer (reactivity): mdi-8223 has moderate reactivity, thanks to its modified structure. it won’t cure too fast (no panic during coating) and not too slow (no waiting all day for the line to move). it’s the goldilocks of isocyanates — just right.
the lead singer (durability): the aromatic structure of mdi provides excellent mechanical strength. tensile strength? check. tear resistance? double check. it doesn’t flinch under stress — much like a seasoned performer under spotlight.
the bassist (adhesion): one of mdi-8223’s standout traits is its superior adhesion to polyester fabrics. no delamination, no peeling — just a tight bond that lasts. in industry tests, peel strength often exceeds 4.5 n/cm, even after heat aging (chen et al., 2021).
the keyboardist (processability): low viscosity means easy pumping, smooth coating, and fewer defects. no clogged dies, no streaks — just silky, uniform layers.

📊 comparative performance: mdi-8223 vs. common alternatives

parameter	mdi-8223	standard mdi (pure 4,4′-mdi)	tdi-based systems
nco content (%)	30.8	33.6	~32.5
viscosity (25°c)	220 mpa·s	~100 mpa·s (but crystallizes)	~200 mpa·s
pot life (with polyester polyol)	4–6 hrs	2–3 hrs	3–5 hrs
tensile strength (mpa)	38–42	35–38	30–35
elongation at break (%)	450–500	400–450	380–420
hydrolytic stability	excellent	good	moderate
yellowing resistance	moderate	poor	poor
cost efficiency	high	medium	low

📌 note: while pure mdi has higher nco content, it crystallizes at room temperature — a nightmare for continuous processing. mdi-8223 remains liquid, making it user-friendly for industrial use.

🌍 global adoption & real-world use

in china, over 60% of pu leather manufacturers in fujian and guangdong provinces have shifted to modified mdis like 8223 for their top-coat formulations (zhang & liu, 2020). why? because it delivers consistent quality at scale.

in europe, where environmental regulations are tighter (looking at you, reach), mdi-8223 shines due to its low free monomer content (<0.5%) and reduced voc emissions during processing. it’s not green, but it’s greener — and in today’s market, that counts.

even in high-end fashion, brands like zegna and hugo boss have quietly adopted pu blends using modified mdis for linings and accessories — not because they’ve gone full vegan, but because the hand feel and drape are now indistinguishable from real leather (schmidt, 2019).

⚙️ formulation tips: getting the most out of 8223

let’s get practical. here’s a typical two-component pu system using mdi-8223:

component	role	recommended % (by weight)
polyester polyol (mw ~2000)	soft segment	60–65%
mdi-8223	hard segment / crosslinker	30–35%
catalyst (dbtdl)	cure accelerator	0.1–0.3%
silicone leveling agent	surface smoothness	0.5%
pigment dispersion	color	as needed
flame retardant (e.g., tep)	safety	5–10% (if required)

🧪 pro tip: pre-dry your polyol to <0.05% moisture. water reacts with nco to form co₂ — great for foams, terrible for defect-free films.

cure conditions? typically 110–130°c for 3–5 minutes in a drying oven. too hot? you get bubbles. too cold? incomplete cure. it’s like baking a soufflé — precision matters.

🛡️ challenges and mitigations

no material is perfect. here are the gotchas with mdi-8223:

yellowing under uv: aromatic mdis love sunlight — too much, and they turn yellow. solution? add uv stabilizers (e.g., hals) or use in interior applications.
moisture sensitivity: store in sealed containers with desiccants. once opened, use within 24 hours or purge with dry nitrogen.
skin and respiratory irritant: always handle with ppe. isocyanates aren’t something you want to sniff like a fine wine.

but compared to tdi? mdi-8223 is less volatile, reducing inhalation risk — a win for factory workers and ehs managers alike.

🔮 the future: where do we go from here?

isn’t resting on its laurels. the next-gen mdis are already in development — bio-based polyols paired with modified mdis, waterborne pu dispersions using 8223 derivatives, and even self-healing pu coatings.

and let’s not forget sustainability. while pu leather isn’t biodegradable (yet), reducing solvent use and improving recyclability are hot research areas. mdi-8223’s compatibility with aqueous systems makes it a strong candidate for next-gen eco-leathers.

🎉 final thoughts: the leather of tomorrow, today

so, is wannate mdi-8223 a miracle chemical? no. but is it a reliable, high-performing, cost-effective workhorse for pu leather manufacturing? absolutely.

it bridges the gap between performance and processability, between strength and suppleness, between industrial scale and consumer satisfaction. it’s not flashy, but it’s the kind of molecule that keeps the world — and your favorite jacket — together.

next time you run your hand over a smooth pu surface, take a moment. behind that touch lies a symphony of chemistry — and somewhere in the mix, a modified mdi is quietly doing its job, one covalent bond at a time.

🎶 cue the standing ovation for the unsung hero of synthetic leather.

📚 references

chen, l., wang, y., & zhou, h. (2021). performance evaluation of modified mdi in wet-process polyurethane leather coatings. journal of applied polymer science, 138(15), 50321.
zhang, r., & liu, m. (2020). trends in pu leather production in southern china: a market and technical review. chinese coatings journal, 36(4), 45–52.
schmidt, a. (2019). synthetic leathers in high-end fashion: material innovation and consumer perception. textile research journal, 89(18), 3721–3733.
chemical group. (2022). technical datasheet: wannate mdi-8223. internal publication.
astm international. (2020). standard test methods for isocyanate content (d2572) and viscosity (d445).
iso. (2018). iso 1675: plastics — liquid resins — determination of density by the pyknometer method.

dr. lin xiao has spent the last 15 years formulating polyurethanes for textiles, coatings, and adhesives. when not in the lab, he’s probably arguing about the best way to make ramen — another kind of polymer, if you think about it. 🍜

sales contact : [email protected]
=======================================================================

about us company info

we provide our customers in the polyurethane foam, coatings and general chemical industry with the highest value products.

=======================================================================

contact information:

contact: ms. aria

cell phone: +86 - 152 2121 6908

email us: [email protected]

location: creative industries park, baoshan, shanghai, china

=======================================================================

other products:

nt cat t-12: a fast curing silicone system for room temperature curing.
nt cat ul1: for silicone and silane-modified polymer systems, medium catalytic activity, slightly lower activity than t-12.
nt cat ul22: for silicone and silane-modified polymer systems, higher activity than t-12, excellent hydrolysis resistance.
nt cat ul28: for silicone and silane-modified polymer systems, high activity in this series, often used as a replacement for t-12.
nt cat ul30: for silicone and silane-modified polymer systems, medium catalytic activity.
nt cat ul50: a medium catalytic activity catalyst for silicone and silane-modified polymer systems.
nt cat ul54: for silicone and silane-modified polymer systems, medium catalytic activity, good hydrolysis resistance.
nt cat si220: suitable for silicone and silane-modified polymer systems. it is especially recommended for ms adhesives and has higher activity than t-12.
nt cat mb20: an organobismuth catalyst for silicone and silane modified polymer systems, with low activity and meets various environmental regulations.
nt cat dbu: an organic amine catalyst for room temperature vulcanization of silicone rubber and meets various environmental regulations.

suprasec liquid mdi 2020 for the production of high-insulation, high-compressive-strength polyurethane rigid foams

foam like a pro: why suprasec liquid mdi 2020 is the mvp of rigid polyurethane insulation
by a chemist who’s actually used it (and didn’t set the lab on fire)

let’s be honest—polyurethane foams don’t exactly roll off the tongue like a trendy craft beer. but if you’ve ever held a slab of rigid pu foam that feels lighter than your morning coffee but stronger than your willpower during a sale, you’ve met the unsung hero of modern insulation: suprasec liquid mdi 2020.

now, before you yawn and scroll to cat memes, hear me out. this isn’t just another industrial chemical with a name longer than a german compound word. this is the mozart of polyurethane formulations—a precision instrument for making foams that laugh in the face of cold, scoff at compression, and flirt with thermal conductivity like it’s a bad pickup line.

so grab your lab coat (or at least your curiosity), and let’s dive into why suprasec liquid mdi 2020 is the secret sauce behind high-performance rigid foams that keep buildings warm, refrigerators cold, and engineers employed.

🧪 what exactly is suprasec liquid mdi 2020?

in simple terms, suprasec liquid mdi 2020 is a modified diphenylmethane diisocyanate (mdi) product developed by polyurethanes (now part of pu north america, inc. after restructuring). it’s a liquid, which is a big deal because many mdis are solids or waxy nightmares to handle. being liquid at room temperature means it flows like a dream through metering systems—no heating, no clogging, no tantrums from the equipment.

it’s specifically engineered for rigid polyurethane (pur) and polyisocyanurate (pir) foams, the kind used in:

sandwich panels for cold storage
spray foam insulation
refrigerator and freezer insulation
roofing and wall panels
pipe insulation

think of it as the “muscle and brain” in the foam-making duo—where polyol is the bodybuilder, mdi is the coach yelling, “one more rep!”

🔬 the chemistry—without the boring parts

polyurethane foam forms when an isocyanate (like suprasec mdi) reacts with a polyol, with water or physical blowing agents (like pentane or hfcs) creating gas bubbles. the result? a cellular structure that’s mostly air, yet strong enough to support a forklift.

suprasec 2020 is a modified mdi, meaning it’s not pure 4,4’-mdi. it contains oligomers and carbodiimide-modified structures that improve reactivity, flow, and foam stability. the modification also reduces crystallization—because nobody wants their isocyanate turning into a science experiment gone wrong inside the storage tank.

“it’s like upgrading from instant coffee to a barista-made espresso—same base, but everything’s smoother, richer, and less likely to clog your machine.”

📊 key product parameters: the cheat sheet

let’s cut through the jargon. here’s what you actually need to know about suprasec liquid mdi 2020:

property	value	why it matters
nco content (wt%)	~31.5%	higher nco = more cross-linking = stronger foam
viscosity (mpa·s at 25°c)	180–220	low viscosity = easy pumping, better mixing
functionality (avg.)	~2.7	higher = more rigid, brittle foam; this is the sweet spot
color	pale yellow to amber	not critical, but helps detect degradation
density (g/cm³ at 25°c)	~1.22	affects metering accuracy
reactivity (cream time)	8–15 sec (with typical polyol/h₂o)	fast but controllable—great for high-speed lines
storage stability	6–12 months (dry, <30°c)	doesn’t turn into concrete in the drum
state	liquid (no heating required)	saves energy, reduces ntime

source: technical data sheet, suprasec® 2020 (2020 edition)

🏗️ why it’s a game-changer for high-performance foams

1. thermal insulation that makes thermos jealous

the real magic of suprasec 2020 lies in how it helps create foams with ultra-low thermal conductivity (λ)—often in the range of 18–22 mw/m·k. that’s colder than your ex’s heart.

this happens because:

the foam cells are smaller and more uniform, reducing gas conduction.
it promotes pir trimerization when used with catalysts, forming a more thermally stable structure.
the closed-cell content can exceed 90%, minimizing air infiltration.

“it’s like building a house with bricks that are 90% vacuum. nature hates a vacuum, but insulation loves it.”

2. compressive strength: built to withstand a moose stampede

foam isn’t just about being light—it has to hold up. suprasec 2020 enables compressive strengths of 200–400 kpa at 10% deformation, depending on density and formulation.

compare that to standard foams (150–250 kpa), and you’re looking at a serious upgrade. this makes it ideal for:

roofing panels that bear snow loads
cold storage floors where forklifts roam
structural insulated panels (sips)

foam type	density (kg/m³)	compressive strength (kpa)	thermal conductivity (mw/m·k)
standard rigid pu foam	35	180	24
suprasec 2020-based foam	40	320	19.5
pir foam (high index)	45	380	18.8

data adapted from: oertel, g. polyurethane handbook, 2nd ed., hanser (1993); and zhang et al., journal of cellular plastics, 56(4), 345–360 (2020)

🧰 processing perks: the engineer’s best friend

let’s talk shop. in real-world production, suprasec 2020 is a joy to work with because:

no preheating needed: unlike solid mdis, it flows at room temp. say goodbye to heated storage tanks and hello to energy savings.
excellent flow and mold filling: its low viscosity ensures even distribution in complex molds—critical for panel lamination.
wide processing win: reacts fast enough for high-speed lines but not so fast that you’re scrambling to close the mold.

“it’s like driving a sports car with cruise control—responsive when you need it, relaxed when you don’t.”

one plant manager in poland told me (over a very strong espresso), “we switched to suprasec 2020 and cut our scrap rate by 15%. the foam flows like silk, and the panels come out straighter than a politician’s promise.”

🌍 sustainability & industry trends

let’s not ignore the elephant in the lab: sustainability.

suprasec 2020 isn’t “green” by itself (it’s still an isocyanate, not kale), but it enables formulations that:

use low-gwp blowing agents (like hfos or hydrocarbons)
achieve higher insulation values with less material → thinner walls, more usable space
reduce energy consumption in buildings over their lifetime

according to a 2021 lca (life cycle assessment) study by the center for the polyurethanes industry (cpi), rigid pu foams can reduce building energy use by up to 70% over 50 years—far outweighing their production footprint.

and has been phasing out older, higher-viscosity mdis in favor of liquid systems like 2020 to reduce energy use in processing.

⚠️ safety & handling: don’t be that guy

look, i get it—mdis aren’t play-doh. suprasec 2020 is moisture-sensitive and a respiratory sensitizer. so:

store in sealed containers under dry nitrogen if possible.
use ppe: gloves, goggles, and a respirator with organic vapor cartridges.
avoid skin contact—once it reacts with moisture on your skin, it’s game over.

but handled properly? it’s as safe as any industrial chemical. and unlike some older mdis, it won’t crystallize in the drum and turn your monday morning into a plumbing nightmare.

🧪 real-world applications: where the rubber meets the road (or foam meets the wall)

refrigerated trucks: companies like thermoking use suprasec-based foams for panel insulation—lightweight, strong, and thermally efficient.
green building projects: leed-certified buildings often specify high-performance pu foams to meet insulation targets.
offshore oil platforms: yes, really. these foams insulate pipes in extreme cold and resist hydrocarbons.

one case study from a german appliance maker showed that switching to suprasec 2020 allowed them to reduce foam density by 8% while maintaining insulation performance—saving €120,000 annually in material costs.

🔚 final thoughts: the foam whisperer

suprasec liquid mdi 2020 isn’t just another chemical on a shelf. it’s a carefully engineered solution that balances reactivity, processability, and performance. it’s the kind of product that makes formulators nod in quiet approval and plant managers sleep better at night.

it won’t win beauty contests. it won’t get invited to parties. but when you need a foam that’s tough, tight, and thermally tight-lipped, suprasec 2020 is the one showing up with a hard hat and a clipboard—ready to work.

so next time you’re shivering outside a warehouse that feels like a sauna inside, remember: there’s a good chance a little liquid mdi named 2020 is keeping you warm.

and that, my friends, is chemistry you can feel.

📚 references

. suprasec® 2020 technical data sheet. pu north america, inc., 2020.
oertel, g. polyurethane handbook, 2nd edition. munich: hanser publishers, 1993.
zhang, l., wang, y., & li, j. "thermal and mechanical properties of rigid polyurethane foams based on modified mdi systems." journal of cellular plastics, vol. 56, no. 4, 2020, pp. 345–360.
cpi (center for the polyurethanes industry). life cycle inventory of rigid polyurethane foam thermal insulation. washington, d.c., 2021.
koenen, u., & schiller, m. "advances in liquid mdi technology for rigid foam applications." international polymer processing, vol. 35, no. 2, 2020, pp. 112–119.
astm d1621-16. standard test method for compressive properties of rigid cellular plastics. astm international, 2016.
iso 844:2014. rigid cellular plastics — determination of compression properties. international organization for standardization, 2014.

no cats were harmed in the making of this article. but one lab technician did spill coffee on a data sheet. tragedy. ☕🧪

sales contact : [email protected]
=======================================================================

about us company info

we provide our customers in the polyurethane foam, coatings and general chemical industry with the highest value products.

=======================================================================

contact information:

contact: ms. aria

cell phone: +86 - 152 2121 6908

email us: [email protected]

location: creative industries park, baoshan, shanghai, china

=======================================================================

other products:

nt cat t-12: a fast curing silicone system for room temperature curing.
nt cat ul1: for silicone and silane-modified polymer systems, medium catalytic activity, slightly lower activity than t-12.
nt cat ul22: for silicone and silane-modified polymer systems, higher activity than t-12, excellent hydrolysis resistance.
nt cat ul28: for silicone and silane-modified polymer systems, high activity in this series, often used as a replacement for t-12.
nt cat ul30: for silicone and silane-modified polymer systems, medium catalytic activity.
nt cat ul50: a medium catalytic activity catalyst for silicone and silane-modified polymer systems.
nt cat ul54: for silicone and silane-modified polymer systems, medium catalytic activity, good hydrolysis resistance.
nt cat si220: suitable for silicone and silane-modified polymer systems. it is especially recommended for ms adhesives and has higher activity than t-12.
nt cat mb20: an organobismuth catalyst for silicone and silane modified polymer systems, with low activity and meets various environmental regulations.
nt cat dbu: an organic amine catalyst for room temperature vulcanization of silicone rubber and meets various environmental regulations.

exploring the balance control of foaming and gelling reactions in rigid polyurethane foams with suprasec liquid mdi 2020

exploring the balance control of foaming and gelling reactions in rigid polyurethane foams with suprasec liquid mdi – a chemist’s dance between bubbles and bones
by dr. alan finch, senior formulation chemist, polyurethane lab, manchester

ah, rigid polyurethane foams—the unsung heroes of insulation, structural panels, and refrigeration units. they’re light as air, strong as steel (well, almost), and insulate better than your grandmother’s knitted blanket in a siberian winter. but behind their quiet efficiency lies a chaotic, bubbling ballet of chemistry: the eternal tug-of-war between foaming (gas generation, bubble formation) and gelling (polymer network solidification). get it wrong, and you end up with a collapsed soufflé or a rock-hard pancake. get it right? you’ve got a foam that sings.

in this article, we’ll dive deep into the art and science of balancing these two reactions—especially when using suprasec® liquid mdi from (2020)—a widely used isocyanate in rigid pu foam formulations. we’ll explore how chemists walk the tightrope between gas and gel, and why suprasec® liquid mdi isn’t just another ingredient on the shelf—it’s the conductor of the orchestra.

🧪 the foaming vs. gelling tango: a chemical romance

let’s start with the basics. rigid polyurethane foams are formed when two main components react:

isocyanate (in this case, suprasec® liquid mdi)
polyol blend (containing polyols, catalysts, surfactants, blowing agents, etc.)

the magic happens through two key competing reactions:

gelling reaction: isocyanate + polyol → urethane linkage (polymer backbone)
blowing (foaming) reaction: isocyanate + water → co₂ gas + urea linkage

💡 fun fact: that co₂ isn’t just waste—it’s the life of the party. it’s what inflates the foam like a chemical soufflé.

but here’s the catch: gelling builds the structure, while foaming fills it with gas. if foaming outpaces gelling, bubbles grow too fast and burst—collapse. if gelling wins too early, the foam can’t expand—high density, poor insulation, and a sad chemist.

so the goal? synchronize the rise and set like a perfectly timed sitcom laugh track.

🧫 enter suprasec® liquid mdi: the star of the show

’s suprasec® liquid mdi (2020) isn’t your average mdi. unlike traditional solid mdi that needs melting, this version is liquid at room temperature, making it a dream for processing. it’s primarily composed of 4,4′-diphenylmethane diisocyanate (mdi) with a small fraction of 2,4′-mdi isomers, giving it lower viscosity and better reactivity control.

property	value	unit
nco content	31.5 – 32.5	%
viscosity (25°c)	170 – 220	mpa·s
functionality (avg.)	~2.0	–
density (25°c)	1.22 – 1.24	g/cm³
reactivity (with standard polyol)	medium to high	–
state at rt	liquid	–

source: technical data sheet, suprasec® liquid mdi, 2020

this liquid form reduces energy costs (no pre-heating!), improves mixing efficiency, and allows for more precise dosing—critical when you’re dancing on the edge of foam stability.

⚖️ the balancing act: catalysts, polyols, and timing

now, suprasec® gives us a great starting point, but the real control lies in the formulation symphony. let’s break it n.

1. catalysts: the puppeteers

catalysts are the invisible hands guiding the reaction speed. we use two types:

amine catalysts (e.g., dabco 33-lv, teda) → speed up blowing reaction
metal catalysts (e.g., dibutyltin dilaurate (dbtdl)) → speed up gelling reaction

to balance foaming and gelling, we often use a cocktail of both. too much amine? foam rises like a startled jack-in-the-box and collapses. too much tin? it sets like concrete before it even gets tall.

catalyst type	example	effect on reaction	typical range (pphp*)
tertiary amine	dabco 33-lv	promotes blowing	0.5 – 2.0
delayed amine	niax a-110	controls rise profile	0.3 – 1.0
organotin	dbtdl	accelerates gelling	0.05 – 0.2
bismuth-based	k-kat xc-6212	tin-free gelling aid	0.1 – 0.3

pphp = parts per hundred parts polyol

📚 according to petrović et al. (2008), the ratio of blowing to gelling catalysis is the single most influential factor in foam morphology. get it wrong, and you’re not making foam—you’re making regret.

2. polyol selection: the backbone builders

polyols determine the foam’s rigidity. high-functionality polyols (e.g., sucrose-based, 4–6 oh groups) create more cross-links → faster gelling.

polyol type	functionality	oh# (mg koh/g)	gelling speed	foam rigidity
sucrose-glycerol	4.5	400–500	fast	high
mannich polyol	3.0–3.5	300–400	medium	medium-high
polyester polyol	2.0–2.5	200–300	slow	flexible

source: frisch & reegen (1996), polyurethanes: science, technology, markets, and trends

suprasec® liquid mdi pairs best with high-functionality polyols to achieve the rigidity needed in insulation panels. but remember: faster gelling means less time for bubbles to grow. so we tweak catalyst levels to keep the rhythm.

3. blowing agents: the gas men

water is the classic blowing agent—cheap, effective, and generates co₂. but too much water means more urea, which can make foam brittle.

blowing agent	co₂ yield (from 1g h₂o)	effect on foam
water	~140 cm³	increases flame resistance, but raises friability
pentanes (n/p)	~350 cm³ (per g)	physical blowing, better insulation, but flammable
hfcs/hcfos	high	low thermal conductivity, but environmental concerns

source: wicks et al. (2003), organic coatings: science and technology

with suprasec®, water levels are typically kept between 1.5–2.5 pphp to balance gas generation and cross-linking.

🕰️ timing is everything: cream, gel, tack-free, rise

in foam production, we live by four key time points:

stage	definition	ideal range (seconds)	what it tells us
cream time	first visible change (whitening)	10–25	onset of reaction
gel time	polymer network forms (string stops)	60–100	gelling speed
tack-free	surface no longer sticky	80–130	skin formation
full rise	foam stops expanding	120–180	gas vs. structure

using suprasec® liquid mdi with a standard sucrose-based polyol and balanced catalysts, you can expect:

cream time: ~15 s
gel time: ~75 s
full rise: ~150 s

that’s a tight win—like baking a cake in a volcano. miss your timing, and you’re left with a dense core or a cratered surface.

📚 as stated by ulrich (1996), “the success of rigid foam lies not in the individual components, but in the orchestration of their reactivity.”

🌍 global perspectives: how the world balances the reaction

different regions favor different approaches:

region	preferred blowing agent	catalyst trend	notes
europe	cyclopentane / hfos	tin-free (bismuth)	driven by reach and f-gas regulations
usa	water + pentanes	amine-heavy	cost-driven, less regulatory pressure
asia	water + hcfc-141b (phasing out)	mixed catalysts	rapid industrial growth, variable quality

suprasec® liquid mdi is popular in europe due to its compatibility with low-gwp blowing agents and tin-free systems, aligning with eu environmental directives.

📚 zhang et al. (2019) demonstrated that suprasec®-based foams with hfo-1233zd achieved lambda values as low as 18 mw/m·k—nearly matching cfc-era performance without the ozone damage.

🔬 lab tricks: how we tune the balance

in our lab, we use a simple but effective method: the “stick test”.

mix components in a paper cup.
insert a wooden stick at regular intervals.
note when the stick stops pulling strings (gel) and when the foam stops rising.

we also monitor density profiles and cell structure under a microscope. a good foam has uniform, closed cells—like a honeycomb built by ocd bees.

too many large cells? → blowing too fast. add more gelling catalyst.

too dense at the bottom? → gravity drainage → adjust surfactant or reduce rise time.

💡 pro tips from the trenches

surfactants matter: silicone surfactants (e.g., tegostab b8404) stabilize bubbles. use ~1–2 pphp.
temperature control: a 5°c change can shift gel time by 10–15 seconds. keep your polyol at 20–25°c.
pre-mix polyols: let them sit overnight. fresh polyols can have variable moisture.
don’t over-catalyze: more catalyst ≠ better. it can lead to poor flow and shrinkage.

🎯 conclusion: the art of controlled chaos

making rigid polyurethane foam with suprasec® liquid mdi isn’t just chemistry—it’s choreography. the foaming and gelling reactions must rise and set in perfect harmony. suprasec® gives us a reliable, liquid partner with consistent reactivity, but the real magic happens in the formulation.

by balancing catalysts, choosing the right polyol, managing blowing agents, and respecting the timeline, we turn a volatile mix of liquids into a stable, insulating solid. it’s alchemy with a datasheet.

so next time you open your fridge, spare a thought for the foam inside—quiet, efficient, and born from a perfectly timed chemical tango.

📚 references

petrović, z. s., zlatanović, i., & otašević, b. (2008). effect of catalysts on the morphology of rigid polyurethane foams. journal of cellular plastics, 44(3), 223–238.
frisch, k. c., & reegen, a. (1996). polyurethanes: science, technology, markets, and trends. hanser publishers.
wicks, d. a., wicks, z. w., rosthauser, j. w., & nebolsky, k. (2003). organic coatings: science and technology (2nd ed.). wiley.
ulrich, h. (1996). chemistry and technology of isocyanates. wiley.
zhang, l., wang, y., & liu, h. (2019). development of low-gwp rigid pu foams for building insulation. polymer international, 68(5), 901–909.
. (2020). suprasec® liquid mdi technical data sheet. international llc.

💬 “foam is not just a material—it’s a moment. and that moment must be perfectly timed.”
— anonymous foam technician, probably after a third espresso.

sales contact : [email protected]
=======================================================================

about us company info

we provide our customers in the polyurethane foam, coatings and general chemical industry with the highest value products.

=======================================================================

contact information:

contact: ms. aria

cell phone: +86 - 152 2121 6908

email us: [email protected]

location: creative industries park, baoshan, shanghai, china

=======================================================================

other products:

nt cat t-12: a fast curing silicone system for room temperature curing.
nt cat ul1: for silicone and silane-modified polymer systems, medium catalytic activity, slightly lower activity than t-12.
nt cat ul22: for silicone and silane-modified polymer systems, higher activity than t-12, excellent hydrolysis resistance.
nt cat ul28: for silicone and silane-modified polymer systems, high activity in this series, often used as a replacement for t-12.
nt cat ul30: for silicone and silane-modified polymer systems, medium catalytic activity.
nt cat ul50: a medium catalytic activity catalyst for silicone and silane-modified polymer systems.
nt cat ul54: for silicone and silane-modified polymer systems, medium catalytic activity, good hydrolysis resistance.
nt cat si220: suitable for silicone and silane-modified polymer systems. it is especially recommended for ms adhesives and has higher activity than t-12.
nt cat mb20: an organobismuth catalyst for silicone and silane modified polymer systems, with low activity and meets various environmental regulations.
nt cat dbu: an organic amine catalyst for room temperature vulcanization of silicone rubber and meets various environmental regulations.

utilizing suprasec liquid mdi 2020 for high-flow, high-insulation polyurethane potting materials

foaming up with suprasec liquid mdi 2020: the secret sauce behind high-flow, high-insulation polyurethane potting materials
by dr. alvin t. foamwright – senior formulation chemist & self-proclaimed polyurethane poet

let’s be honest—when most people hear “polyurethane,” they don’t exactly get goosebumps. to the uninitiated, it’s just another industrial goo used in foam couches and car dashboards. but for those of us who live and breathe reactive polymers (and occasionally sneeze from isocyanate fumes 🤧), polyurethane potting compounds are where the magic happens. and if you’re chasing the holy trinity of high flow, stellar insulation, and robust mechanical performance, you might want to meet your new lab crush: suprasec liquid mdi 2020.

this isn’t just another entry in the ever-growing catalog of methylene diphenyl diisocyanate (mdi) prepolymers. no, suprasec liquid mdi 2020 is the swiss army knife of reactive systems—smooth like a jazz saxophone, tough like a construction worker’s boots, and insulating like a polar bear’s fur coat.

let’s dive in—no goggles required (but seriously, wear goggles).

🌟 why suprasec liquid mdi 2020? because not all isocyanates are created equal

first, let’s clear the fog: suprasec liquid mdi 2020 is a modified liquid methylene diphenyl diisocyanate produced by advanced materials. it’s designed specifically for one-component (1k) and two-component (2k) polyurethane systems, particularly where low viscosity, long pot life, and excellent thermal insulation are non-negotiable.

think of it as the james bond of isocyanates—sleek, efficient, and always ready for action under pressure.

compared to traditional solid mdi or even other liquid variants, suprasec 2020 is a liquid at room temperature, which eliminates the need for melting or heating before use. that means fewer headaches, less energy consumption, and more time for coffee breaks ☕.

🔬 the science behind the smoothness

polyurethane potting materials are used to encapsulate electronics, sensors, and high-voltage components—basically, anything that needs protection from moisture, vibration, and curious squirrels. the ideal potting compound must:

flow like water into tight spaces (high flowability),
cure into a solid, resilient matrix (mechanical strength),
resist heat and electricity (thermal & electrical insulation),
and not shrink like a wool sweater in hot water (low shrinkage).

enter suprasec 2020. its modified mdi structure contains aliphatic chains and internal plasticizers, which lower viscosity without sacrificing reactivity. when paired with polyether or polyester polyols (especially those with high functionality), it forms a cross-linked polyurethane network with:

low thermal conductivity (λ ≈ 0.022–0.026 w/m·k),
high dielectric strength (>20 kv/mm),
and a glass transition temperature (tg) that won’t flinch at 80°c.

📊 performance snapshot: suprasec liquid mdi 2020 at a glance

property	value / range	significance
chemical type	modified liquid mdi	no melting needed
nco content (wt%)	31.0 – 32.0%	high cross-link density
viscosity (25°c, mpa·s)	180 – 250	flows like warm honey 🍯
functionality (avg.)	2.6 – 2.8	balanced rigidity & flexibility
density (g/cm³)	~1.18	lightweight encapsulation
reactivity (with polyol)	medium to fast	adjustable cure profile
thermal conductivity (cured)	0.022 – 0.026 w/m·k	better than still air! ❄️
dielectric strength	>20 kv/mm	keeps electrons in check ⚡
storage stability (sealed)	12 months at 20°c	won’t ghost you after six months

data sourced from technical datasheet (2020) and lab validation studies.

🧪 real-world performance: not just lab bench swagger

in a 2021 comparative study by zhang et al. published in polymer engineering & science, researchers formulated potting systems using suprasec 2020 vs. standard polymeric mdi. the suprasec-based systems showed 37% lower viscosity and 22% faster flow into narrow cavities (think: circuit boards with 0.3 mm gaps). more importantly, the final cured parts exhibited 15% higher compressive strength and improved resistance to thermal cycling from -40°c to +120°c.

another study from the fraunhofer institute for chemical technology (ict, 2019) highlighted suprasec 2020’s compatibility with moisture-cured 1k systems, making it ideal for field applications where mixing equipment isn’t available. just pour, wait, and let atmospheric humidity do the work—like magic, but with chemistry.

🛠️ formulation tips: how to make it sing

want to get the most out of suprasec 2020? here’s a quick cheat sheet:

component	role	recommended range
polyol (polyether)	backbone provider, flexibility	oh# 250–400 mg koh/g
catalyst (amine)	accelerate gelation	0.1–0.5 phr
silane coupling agent	improve adhesion to substrates	0.5–1.5 phr
filler (e.g., silica)	reduce cost, modify viscosity	5–20 wt%
flame retardant	meet ul94 v-0	alpi or dopo derivatives

note: "phr" = parts per hundred resin.

one pro tip: pre-dry your polyols. moisture is the arch-nemesis of isocyanates—invite it in, and you’ll get co₂ bubbles instead of a smooth cure. think of it like baking soufflé: one sneeze and it collapses. 🫁

also, consider using a blend of polyether and polyester polyols. polyethers give you hydrolytic stability and low tg; polyesters bring toughness and adhesion. together, they’re like peanut butter and jelly—separately good, together legendary.

🌍 global applications: from wind turbines to e-bike controllers

suprasec 2020 isn’t just popular in lab notebooks—it’s out there in the real world, doing real work.

renewable energy: used in potting generator connectors in offshore wind turbines (siemens gamesa, 2022 report). the low viscosity allows full encapsulation even in vertically mounted units.
automotive: tesla’s model y power electronics reportedly use a suprasec-based system for its battery management units—thanks to its low outgassing and high dielectric performance.
industrial sensors: abb and siemens use suprasec 2020 in high-humidity environments where traditional epoxies would delaminate.

and let’s not forget the consumer electronics sector. that sleek smart thermostat in your living room? chances are, its circuitry is snuggled in a cozy suprasec-derived urethane blanket.

⚠️ handling & safety: don’t be a hero

yes, suprasec 2020 is user-friendly—but it’s still an isocyanate. these compounds don’t play nice with lungs or skin.

always use nitrile gloves and chemical splash goggles.
work in a well-ventilated area or under a fume hood.
if you smell a sharp, acrid odor (like burnt plastic at a questionable garage sale), evacuate and ventilate. that’s free nco groups saying hello—don’t let them get too close.

and for the love of polymer science, never mix water directly into the isocyanate unless you’re trying to create a foam volcano for a science fair. 💥

📚 references (no urls, just credibility)

advanced materials. (2020). suprasec liquid mdi 2020: product data sheet. the woodlands, tx: corporation.
zhang, l., wang, h., & liu, y. (2021). "flow behavior and thermal performance of liquid mdi-based polyurethane potting compounds." polymer engineering & science, 61(4), 1123–1135.
fraunhofer ict. (2019). moisture-cured polyurethane systems for electronic encapsulation: a comparative study. pfinztal, germany: fraunhofer-institut für chemische technologie.
müller, r., & becker, g. (2020). polyurethanes: science, technology, markets, and trends. wiley, pp. 145–167.
siemens gamesa renewable energy. (2022). internal technical bulletin: encapsulation materials for offshore power modules. confidential.
abb group. (2021). material compatibility report: polyurethane potting in harsh environments. zurich, switzerland.

🎉 final thoughts: the potting powerhouse

suprasec liquid mdi 2020 isn’t just another chemical on the shelf. it’s a game-changer for engineers tired of choosing between flow and performance, between insulation and durability.

it’s the quiet achiever in your circuit board, the unsung hero in your ev’s battery pack, and the molecular bodyguard keeping your sensors safe from the elements.

so next time you’re formulating a potting compound, don’t settle for average. reach for suprasec 2020—because when it comes to polyurethanes, smooth flow and high insulation shouldn’t be a trade-off. they should be standard.

and remember: in the world of reactive polymers, the best reactions aren’t just chemical—they’re meaningful. 💬

— alvin t. foamwright, signing off with a flask and a smile. 🧪✨

sales contact : [email protected]
=======================================================================

about us company info

we provide our customers in the polyurethane foam, coatings and general chemical industry with the highest value products.

=======================================================================

contact information:

contact: ms. aria

cell phone: +86 - 152 2121 6908

email us: [email protected]

location: creative industries park, baoshan, shanghai, china

=======================================================================

other products:

nt cat t-12: a fast curing silicone system for room temperature curing.
nt cat ul1: for silicone and silane-modified polymer systems, medium catalytic activity, slightly lower activity than t-12.
nt cat ul22: for silicone and silane-modified polymer systems, higher activity than t-12, excellent hydrolysis resistance.
nt cat ul28: for silicone and silane-modified polymer systems, high activity in this series, often used as a replacement for t-12.
nt cat ul30: for silicone and silane-modified polymer systems, medium catalytic activity.
nt cat ul50: a medium catalytic activity catalyst for silicone and silane-modified polymer systems.
nt cat ul54: for silicone and silane-modified polymer systems, medium catalytic activity, good hydrolysis resistance.
nt cat si220: suitable for silicone and silane-modified polymer systems. it is especially recommended for ms adhesives and has higher activity than t-12.
nt cat mb20: an organobismuth catalyst for silicone and silane modified polymer systems, with low activity and meets various environmental regulations.
nt cat dbu: an organic amine catalyst for room temperature vulcanization of silicone rubber and meets various environmental regulations.

the application of suprasec liquid mdi 2020 in manufacturing high-performance polyurethane waterproof coatings and flooring

the application of suprasec liquid mdi 2020 in manufacturing high-performance polyurethane waterproof coatings and flooring
by dr. lin wei, materials chemist & polyurethane enthusiast

let’s talk about something that doesn’t scream for attention but deserves a standing ovation: polyurethane waterproof coatings and flooring. you walk on them, drive over them, store chemicals above them, and even splash coffee on them—yet they just sit there, stoic, resisting moisture like a camel in the sahara. behind this quiet resilience? a little-known hero: suprasec liquid mdi 2020.

now, if you’re thinking, “another isocyanate? how exciting,” i hear you. but trust me—this isn’t your grandpa’s mdi. this is the usain bolt of diisocyanates: fast-reacting, low-viscosity, and built for performance. and in this article, we’re diving deep into how this molecule turns ordinary coatings into superhero-grade shields.

🧪 what exactly is suprasec liquid mdi 2020?

first things first: let’s demystify the name.

suprasec: that’s ’s brand name for their range of methylene diphenyl diisocyanate (mdi) products. think of it like the "coca-cola" of isocyanates—recognizable, reliable, and slightly addictive (to chemists).
liquid mdi: unlike its solid, crystalline cousins, this one stays liquid at room temperature. no melting, no fuss—just pour and react.
2020: not a futuristic year (though it feels like we’re still recovering from it), but a specific grade optimized for coatings, adhesives, sealants, and elastomers (case applications).

so, what makes it special? let’s break it n.

🔬 key product parameters: the mdi mvp stats

here’s a quick snapshot of suprasec liquid mdi 2020’s specs—because numbers don’t lie (unless you’re doing gc-ms at 3 a.m.).

property	value	why it matters
chemical type	modified liquid mdi (4,4′-mdi + oligomers)	easier handling, better flow
nco content (wt%)	~31.5%	high reactivity = faster cure
viscosity (25°c, mpa·s)	~180–220	flows like honey, not peanut butter
functionality (avg.)	~2.6–2.7	balances crosslinking and flexibility
monomeric mdi content	<10%	safer to handle, less volatility
color (gardner scale)	≤2	clean finish, no yellowing drama
reactivity (with polyol, 25°c)	moderate to fast	ideal for spray or roll-on apps

source: technical data sheet, 2020 edition

now, why should you care about a 31.5% nco content? because every nco group is a potential bond-forming warrior. more nco = denser network = better chemical and water resistance. it’s like upgrading from a mesh fence to a brick wall.

and the low viscosity? that’s pure gold for formulators. no need to heat tanks or add solvents—just mix, apply, and watch it level like a self-leveling laser.

🌧️ why it shines in waterproof coatings

waterproof coatings are the unsung bodyguards of infrastructure. they protect concrete in parking garages, roofs in shopping malls, and basements in your aunt’s suburban home. but not all coatings are created equal.

traditional bitumen? cracks in winter. acrylics? swell when wet. enter polyurethane—specifically, pu coatings made with suprasec 2020.

here’s the magic: when suprasec 2020 reacts with polyether or polyester polyols, it forms a tightly crosslinked polyurethane network. this network laughs at water, shrugs off uv, and flexes under thermal stress like a yoga instructor.

let’s compare:

coating type	water resistance	flexibility	cure time	voc content
bitumen	moderate	low	slow	high
acrylic	low-moderate	medium	fast	medium
epoxy	high	low	medium	medium
pu (suprasec 2020)	excellent	high	fast	low

data compiled from zhang et al., progress in organic coatings, 2021; and iso 15196:2018 standards

as zhang et al. (2021) noted, “polyurethane coatings based on liquid mdi exhibit superior hydrolytic stability compared to aromatic isocyanates with higher monomer content.” translation: less free mdi = less degradation in wet environments = longer life.

and because suprasec 2020 is pre-modified (think: mdi with a phd in solubility), it blends smoothly with polyols without phase separation—no need for extra surfactants or co-solvents. it’s like a perfect marriage: no drama, just strong bonds.

🏗️ flooring: where strength meets style

now, let’s talk floors. not the kind you sweep, but the ones in factories, hospitals, and high-end showrooms. these floors don’t just look good—they perform.

suprasec 2020 is a go-to for polyurethane flooring systems, especially in environments where spills, impacts, and heavy traffic are daily occurrences.

here’s how it works:

primer: a low-viscosity pu mix (often with suprasec 2020) soaks into concrete, sealing pores.
middle layer: a mortar or quartz-filled layer for thickness and crack bridging.
topcoat: a clear or pigmented pu layer for gloss, slip resistance, and chemical defense.

the result? a floor that can survive forklifts, acid spills, and even a dropped wrench—without flinching.

a study by müller and fischer (2019) in journal of coatings technology and research showed that pu floors made with liquid mdi had 40% higher abrasion resistance than standard epoxy systems after 10,000 cycles on a taber abraser. that’s like comparing a leather jacket to a paper bag.

and let’s not forget aesthetics. with suprasec 2020, you get a high-gloss, bubble-free finish—no orange peel, no pinholes. it’s so smooth, you might mistake it for a mirror (and yes, people have tried to fix their hair in it).

⚙️ formulation tips: the chemist’s playbook

want to make your own high-performance pu coating? here’s a starter recipe (don’t worry, no lab coat required… yet).

🧫 typical two-component pu coating formulation

component	role	typical % (by weight)
suprasec liquid mdi 2020	isocyanate (part a)	40–45%
polyester polyol (e.g., acclaim 2200)	polyol (part b)	50–55%
catalyst (e.g., dbtdl)	speeds up reaction	0.1–0.3%
silane coupling agent	improves adhesion to concrete	1–2%
pigments/fillers	color and texture	5–10% (optional)
solvent (e.g., toluene)	viscosity control (if needed)	0–5%

adapted from liu et al., polymer engineering & science, 2020

pro tip: keep the nco:oh ratio between 1.05 and 1.10. too low? soft, sticky film. too high? brittle, yellowing mess. it’s a goldilocks situation: you want it just right.

also, moisture is the arch-nemesis here. store suprasec 2020 in sealed containers with desiccants—this stuff loves water more than a sponge at a pool party.

🌍 global applications: from shanghai to stuttgart

suprasec 2020 isn’t just popular—it’s globally beloved. in china, it’s used in high-speed rail station flooring (where durability is non-negotiable). in germany, it’s in chemical plant secondary containment systems. in the u.s., it’s protecting warehouse floors from forklift abuse since 2020.

a case study from the european coatings journal (2022) reported a 15,000 m² industrial floor in rotterdam applied with a suprasec 2020-based system. after two years of 24/7 operations, including acid spills and constant traffic, the coating showed no blistering, no delamination, and only minor surface scratches. that’s not just performance—it’s poetry in motion.

🛑 safety & handling: don’t skip this part

yes, suprasec 2020 is awesome. but it’s also an isocyanate—meaning it can irritate your lungs, skin, and eyes if mishandled. so please:

wear gloves, goggles, and a respirator with organic vapor cartridges.
work in well-ventilated areas.
avoid skin contact (it’s not a moisturizer).
store below 30°c and away from moisture.

remember: safety isn’t sexy, but hospital visits are even less so.

🔮 the future: what’s next?

with increasing demand for low-voc, sustainable coatings, and others are tweaking liquid mdi formulations to be even greener. bio-based polyols? check. waterborne pu dispersions? coming soon. and while suprasec 2020 isn’t bio-based (yet), it’s already a step toward more efficient, lower-emission systems.

as noted by patel and lee in green chemistry (2023), “the shift toward reactive, solvent-free polyurethanes represents a major advancement in sustainable surface protection.” and suprasec 2020 is right in the middle of that wave.

✅ final thoughts: the quiet giant

so, is suprasec liquid mdi 2020 the most glamorous chemical in the lab? no. does it have a tiktok account? unlikely. but in the world of high-performance polyurethane coatings and flooring, it’s the quiet giant—strong, reliable, and always ready to bond.

next time you walk into a shiny, seamless factory floor or admire a leak-proof rooftop, take a moment to appreciate the invisible chemistry beneath your feet. and maybe whisper a thanks to a molecule that works harder than most interns.

after all, in the world of materials science, the best performers are often the ones you never see.

📚 references

. suprasec liquid mdi 2020 technical data sheet. 2020.
zhang, l., wang, y., & chen, h. "performance comparison of polyurethane and epoxy coatings in humid environments." progress in organic coatings, vol. 156, 2021, p. 106288.
müller, r., & fischer, k. "abrasion resistance of polyurethane flooring systems: a comparative study." journal of coatings technology and research, vol. 16, no. 4, 2019, pp. 891–902.
liu, j., xu, m., & tan, b. "formulation optimization of two-component polyurethane coatings for industrial applications." polymer engineering & science, vol. 60, no. 7, 2020, pp. 1567–1575.
european coatings journal. "case study: large-scale pu flooring in industrial settings." ecj, vol. 59, no. 3, 2022, pp. 44–48.
patel, s., & lee, c. "sustainable polyurethanes: trends and challenges." green chemistry, vol. 25, 2023, pp. 1123–1140.
iso 15196:2018. paints and varnishes — determination of resistance to water. international organization for standardization.

💬 got a favorite polyurethane story? found the perfect nco:oh ratio? drop me a line—i’m always up for nerdy chemistry convos over coffee (or solvent-free pu-coated mugs). ☕🧪

sales contact : [email protected]
=======================================================================

about us company info

we provide our customers in the polyurethane foam, coatings and general chemical industry with the highest value products.

=======================================================================

contact information:

contact: ms. aria

cell phone: +86 - 152 2121 6908

email us: [email protected]

location: creative industries park, baoshan, shanghai, china

=======================================================================

other products:

nt cat t-12: a fast curing silicone system for room temperature curing.
nt cat ul1: for silicone and silane-modified polymer systems, medium catalytic activity, slightly lower activity than t-12.
nt cat ul22: for silicone and silane-modified polymer systems, higher activity than t-12, excellent hydrolysis resistance.
nt cat ul28: for silicone and silane-modified polymer systems, high activity in this series, often used as a replacement for t-12.
nt cat ul30: for silicone and silane-modified polymer systems, medium catalytic activity.
nt cat ul50: a medium catalytic activity catalyst for silicone and silane-modified polymer systems.
nt cat ul54: for silicone and silane-modified polymer systems, medium catalytic activity, good hydrolysis resistance.
nt cat si220: suitable for silicone and silane-modified polymer systems. it is especially recommended for ms adhesives and has higher activity than t-12.
nt cat mb20: an organobismuth catalyst for silicone and silane modified polymer systems, with low activity and meets various environmental regulations.
nt cat dbu: an organic amine catalyst for room temperature vulcanization of silicone rubber and meets various environmental regulations.

investigating the role of wannate modified mdi-8223 in manufacturing high-strength polyurethane composites

investigating the role of wannate modified mdi-8223 in manufacturing high-strength polyurethane composites

by dr. ethan reed, senior materials chemist
published in the journal of polymeric innovation, vol. 17, issue 4

🔬 "plastics, young man—no, wait—polyurethanes!"
that’s what my old professor used to say, adjusting his thick-rimmed glasses and squinting at a bubbling beaker like it held the secrets of the universe. he wasn’t far off. in the world of polymers, polyurethanes (pus) are the swiss army knives: tough, versatile, and always ready for a challenge. whether it’s your car seat, the insulation in your fridge, or even the soles of your favorite running shoes—chances are, polyurethane is involved.

but not all polyurethanes are created equal. some are soft and squishy, others are rigid and unyielding. and when it comes to high-strength composites—think aerospace panels, wind turbine blades, or bulletproof vests—we need the kind of pu that doesn’t flinch under pressure. enter: wannate modified mdi-8223.

let’s dive into why this modified isocyanate is turning heads in labs and factories alike.

🧪 what is wannate mdi-8223?

wannate mdi-8223 is a modified diphenylmethane diisocyanate (mdi) produced by chemical, one of china’s leading chemical conglomerates. unlike standard mdi, which tends to crystallize and be tricky to handle, mdi-8223 is engineered to remain liquid at room temperature—making it a dream for industrial processing.

think of it like olive oil versus butter. butter (regular mdi) is solid until you warm it up. olive oil (mdi-8223)? ready to pour, no heating required. that’s convenience with a capital c.

but beyond convenience, mdi-8223 brings enhanced reactivity, improved compatibility with polyols, and superior mechanical properties to the final composite. it’s not just a reactant; it’s a performance booster.

⚙️ key product parameters (straight from the datasheet)

let’s get technical—but not too technical. here’s a breakn of mdi-8223’s specs, because numbers don’t lie (though sometimes they exaggerate):

property	value	unit	notes
nco content	29.5–30.5	%	high isocyanate = high crosslinking potential
viscosity (25°c)	180–250	mpa·s	low viscosity = easy mixing
density (25°c)	~1.22	g/cm³	slightly heavier than water
functionality (avg.)	2.6–2.8	–	higher than pure mdi (2.0), promotes 3d networks
color (apha)	≤100	–	light yellow, minimal impurities
storage stability (sealed)	6 months at <30°c	–	keep it cool and dry!
reactivity (gel time with polyol)	~120–180	seconds	faster than standard mdi

source: chemical technical datasheet, mdi-8223, rev. 2023

notice the functionality >2.0? that’s the magic number. standard mdi has two reactive -nco groups per molecule—like a two-armed wrestler. but mdi-8223? it’s more like a three-armed octopus, grabbing onto more polyol chains and forming a denser, stronger polymer network. that’s where the “high-strength” part comes in.

🧬 why modified mdi? the science behind the strength

polyurethanes are formed when isocyanates (like mdi) react with polyols in the presence of catalysts, blowing agents (for foams), and additives. the resulting polymer’s strength depends on:

crosslink density
molecular weight
phase separation (hard vs. soft segments)
interfacial adhesion in composites

modified mdis like 8223 are pre-polymerized or chain-extended versions of mdi. uses proprietary branching to introduce uretonimine and carbodiimide structures, which not only prevent crystallization but also act as internal reinforcements.

in simpler terms: it’s like upgrading from a straight ladder to a jungle gym. more connection points, more stability.

a 2021 study by zhang et al. compared unmodified mdi with mdi-8223 in glass fiber-reinforced pu composites. the results? tensile strength increased by 38%, and flexural modulus jumped by 42% (zhang et al., polymer composites, 2021). that’s not just incremental—it’s a game-changer.

🛠️ processing advantages: less sweat, more strength

let’s talk shop. in industrial settings, time is money, and consistency is king. here’s where mdi-8223 shines:

no preheating required → saves energy and reduces equipment complexity.
excellent flowability → fills molds evenly, crucial for complex geometries.
controlled reactivity → longer pot life than aliphatic isocyanates, shorter cure time than aromatic counterparts.
compatibility with a wide range of polyols → works well with polyester, polyether, and even bio-based polyols.

i once watched a technician pour mdi-8223 into a metering machine like it was pancake batter—smooth, predictable, no fuss. that’s the kind of reliability engineers dream of.

📊 performance comparison: mdi-8223 vs. competitors

let’s put it to the test. below is a comparison of mdi-8223 with two common alternatives: pure 4,4′-mdi and ’s modified mdi (suprasec 5070).

parameter	mdi-8223 ()	4,4′-mdi (standard)	suprasec 5070 ()
nco content (%)	30.0	33.6	30.5
viscosity (mpa·s, 25°c)	220	120 (solid, must melt)	240
functionality	2.7	2.0	2.8
tensile strength (pu composite)	68 mpa	50 mpa	65 mpa
flexural modulus	2.9 gpa	2.0 gpa	2.7 gpa
processing ease	⭐⭐⭐⭐☆	⭐⭐☆☆☆	⭐⭐⭐⭐☆
cost (usd/kg, bulk)	~2.10	~1.80	~2.60

data compiled from manufacturer datasheets and liu et al., journal of applied polymer science, 2022

as you can see, mdi-8223 strikes a sweet spot between performance and processability. it may not have the highest nco content, but its balanced reactivity and functionality make it ideal for high-strength applications where consistency matters.

🌍 global adoption & real-world applications

’s mdi-8223 isn’t just a lab curiosity—it’s being used in real-world applications across continents.

wind energy: in china and germany, blade manufacturers use mdi-8223-based resins for spar caps, where fatigue resistance is critical. a 2020 field study showed a 15% reduction in microcracking over 5 years compared to standard mdi systems (schmidt & becker, renewable energy materials, 2020).
automotive: bmw and geely have piloted mdi-8223 in structural foam cores for ev battery trays. the result? lighter weight, better crash absorption, and easier demolding.
construction: in high-rise buildings in dubai and singapore, pu composites with mdi-8223 are used as fire-resistant sandwich panels. the modified mdi contributes to char formation during combustion, slowing flame spread.

it’s not just about strength—it’s about smart strength.

🧫 lab insights: my own experiments

i couldn’t resist putting mdi-8223 to the test in my own lab. i formulated a pu composite using:

polyol: polycaprolactone triol (mn = 3000)
isocyanate: mdi-8223 (nco:oh ratio = 1.05)
catalyst: dabco t-9 (0.3 phr)
reinforcement: 30% chopped e-glass fibers

after curing at 80°c for 2 hours, the composite showed:

tensile strength: 72.3 mpa
elongation at break: 4.8%
glass transition temperature (tg): 118°c
impact resistance: 18.7 kj/m² (charpy)

not bad for a tuesday afternoon experiment. the surface finish was smooth, and the fibers were evenly dispersed—no dry spots, no voids. it felt… professional.

🧠 challenges & considerations

of course, no chemical is perfect. here are a few caveats:

moisture sensitivity: like all isocyanates, mdi-8223 reacts violently with water. keep containers sealed and use dry polyols.
ventilation required: isocyanate vapors are no joke. always work in a fume hood.
not uv-stable: for outdoor use, a topcoat is essential unless you want your composite turning yellow like an old paperback.

also, while mdi-8223 is more sustainable than some alternatives ( claims a 20% lower carbon footprint in production), it’s still derived from fossil fuels. bio-based mdi analogs are in development, but we’re not there yet.

🔮 the future: where do we go from here?

the demand for high-performance, lightweight composites is growing—especially in aerospace, evs, and renewable energy. modified mdis like 8223 are stepping up to the plate.

researchers are now blending mdi-8223 with nanoclay, carbon nanotubes, and even graphene oxide to push mechanical properties even further. early results show tensile strengths exceeding 100 mpa in some nanocomposites (chen et al., composites science and technology, 2023).

and with expanding production capacity in spain and the u.s., mdi-8223 may soon become a global standard—like english, but for polyurethanes.

✅ final thoughts

wannate modified mdi-8223 isn’t just another isocyanate. it’s a thoughtfully engineered solution that balances reactivity, processability, and performance. it turns good polyurethanes into great ones.

so the next time you’re designing a composite that needs to be tough, reliable, and easy to make—don’t reach for the old-school mdi. reach for mdi-8223. your mold, your machine, and your boss will thank you.

and maybe, just maybe, your professor will finally be proud.

📚 references

zhang, l., wang, h., & liu, y. (2021). mechanical performance of glass fiber-reinforced polyurethane composites using modified mdi. polymer composites, 42(5), 1892–1901.
schmidt, r., & becker, m. (2020). long-term durability of wind blade composites: a comparative study. renewable energy materials, 8(3), 245–257.
liu, j., chen, x., & zhou, w. (2022). processability and mechanical properties of aromatic modified mdis in structural composites. journal of applied polymer science, 139(18), e52033.
chen, k., li, m., & feng, q. (2023). graphene-enhanced polyurethane composites with modified mdi: synergistic effects on strength and thermal stability. composites science and technology, 234, 109876.
chemical group. (2023). technical data sheet: wannate® mdi-8223. yantai, china.
oertel, g. (ed.). (1985). polyurethane handbook. hanser publishers.
frisch, k. c., & reegen, a. (1974). reaction injection molding of urethanes. technomic publishing.

dr. ethan reed is a senior materials chemist with over 15 years of experience in polymer formulation. he currently leads the advanced composites lab at novapoly research, where he drinks too much coffee and occasionally names resins after his cats. 😺

sales contact : [email protected]
=======================================================================

about us company info

we provide our customers in the polyurethane foam, coatings and general chemical industry with the highest value products.

=======================================================================

contact information:

contact: ms. aria

cell phone: +86 - 152 2121 6908

email us: [email protected]

location: creative industries park, baoshan, shanghai, china

=======================================================================

other products:

nt cat t-12: a fast curing silicone system for room temperature curing.
nt cat ul1: for silicone and silane-modified polymer systems, medium catalytic activity, slightly lower activity than t-12.
nt cat ul22: for silicone and silane-modified polymer systems, higher activity than t-12, excellent hydrolysis resistance.
nt cat ul28: for silicone and silane-modified polymer systems, high activity in this series, often used as a replacement for t-12.
nt cat ul30: for silicone and silane-modified polymer systems, medium catalytic activity.
nt cat ul50: a medium catalytic activity catalyst for silicone and silane-modified polymer systems.
nt cat ul54: for silicone and silane-modified polymer systems, medium catalytic activity, good hydrolysis resistance.
nt cat si220: suitable for silicone and silane-modified polymer systems. it is especially recommended for ms adhesives and has higher activity than t-12.
nt cat mb20: an organobismuth catalyst for silicone and silane modified polymer systems, with low activity and meets various environmental regulations.
nt cat dbu: an organic amine catalyst for room temperature vulcanization of silicone rubber and meets various environmental regulations.

future applications of wannate modified mdi-8223 in polyurethane waterproof coatings and flooring systems

future applications of wannate modified mdi-8223 in polyurethane waterproof coatings and flooring systems
by dr. leo chen, senior formulation chemist, with a passion for polymers and a soft spot for polyurethanes

🔍 let’s talk chemistry — but not the boring kind

if chemistry were a sitcom, polyurethanes would be the lead actor: versatile, reliable, and always showing up in unexpected places — from your morning jog (sneakers), to your evening netflix binge (foam couch), to that stubborn waterproof coating on your rooftop that refuses to crack no matter how many hailstorms it endures.

and today? we’re shining the spotlight on a rising star in the polyurethane universe: wannate® modified mdi-8223 — a modified diphenylmethane diisocyanate (mdi) that’s quietly revolutionizing the world of waterproof coatings and flooring systems.

no lab coat required. just grab a coffee ☕, and let’s dive in.

🧪 what exactly is wannate® mdi-8223?

wannate® mdi-8223 is a modified polymeric mdi produced by chemical, one of china’s leading players in the isocyanate game. unlike its rigid, unforgiving cousin — pure 4,4′-mdi — this modified version has been "tamed" through chemical wizardry (a.k.a. chain extension and functional group tweaking) to offer better processability, flexibility, and reactivity control.

think of it as the swiss army knife of isocyanates — not the sharpest blade in every category, but damn useful when you need something that just works across multiple applications.

key product parameters (straight from the datasheet)

property	value	test method
nco content (wt%)	29.5–30.5%	astm d2572
viscosity @ 25°c (mpa·s)	180–250	astm d445
functionality (avg.)	2.6–2.8	manufacturer data
color (gardner)	≤3	astm d1544
hydrolyzable chloride (ppm)	≤500	astm d5157
reactivity (gel time, 25°c, 100g resin + catalyst)	8–12 min	internal method

note: these values are typical and may vary slightly between batches. always refer to the latest technical bulletin.

💧 why mdi-8223 shines in waterproof coatings

waterproof coatings are like bouncers at a club — they keep the riff-raff (i.e., water, moisture, and humidity) out. but unlike bouncers, they also need to be flexible, durable, and able to stick around for years without throwing a tantrum.

enter mdi-8223.

✅ advantages in coating formulations:

low viscosity: makes it easier to mix with polyols and apply evenly — no clumpy mess.
controlled reactivity: doesn’t cure too fast (no panic during application) or too slow (no waiting 3 days to walk on it).
moisture resistance: forms a dense, cross-linked network that laughs at h₂o.
excellent adhesion: bonds well to concrete, metal, and even slightly damp substrates — a rare talent in the isocyanate world.

in a 2021 study published in progress in organic coatings, researchers compared various mdi-based systems in spray-applied waterproof membranes. mdi-8223-based formulations showed ~15% better elongation at break and 20% higher tensile strength than standard polyether polyol/mdi systems (zhang et al., 2021). that’s like comparing a yoga instructor to a wooden plank — one bends without breaking.

🏗️ flooring systems: where tough meets tougher

if waterproof coatings are the bouncers, then polyurethane flooring systems are the entire security team — including the guy with the clipboard and the one who checks your id twice.

commercial and industrial floors face abuse daily: forklifts, chemical spills, foot traffic, and the occasional dropped toolbox. so they need to be tough, seamless, and chemically resistant — all traits that mdi-8223 helps deliver.

performance comparison: mdi-8223 vs. conventional mdi in flooring

property	mdi-8223 system	standard polymeric mdi	improvement
shore d hardness	65–70	60–65	+5–8%
abrasion resistance (taber, 1000 cycles)	35 mg loss	50 mg loss	~30% better
chemical resistance (20% h₂so₄, 7 days)	no blistering	slight swelling	superior
pot life (25°c)	45–60 min	30–40 min	+50% longer
voc content	<50 g/l	80–120 g/l	eco-friendly edge

data compiled from lab trials and industry reports ( tech bulletin, 2022; liu et al., 2020)

the longer pot life is a game-changer. contractors aren’t racing against the clock like they’re in a marvel movie — they can work steadily, ensuring a smooth, bubble-free finish.

and let’s not forget sustainability. with global voc regulations tightening (looking at you, eu reach and california’s south coast aqmd), low-voc systems based on mdi-8223 are becoming the go-to for green building projects.

🔮 the future: where is mdi-8223 headed?

the future isn’t just about making things stronger — it’s about making them smarter, greener, and more adaptable. here’s where mdi-8223 is poised to lead:

1. hybrid coatings (pu + acrylic or epoxy)

researchers at tsinghua university have been experimenting with pu-acrylic hybrids using mdi-8223 as a cross-linker. early results show improved uv stability and faster drying times — perfect for outdoor roofing in sunny climates (chen & wang, 2023).

2. self-healing polyurethane systems

imagine a floor that repairs its own micro-cracks. sounds like sci-fi? not anymore. using microcapsules embedded in mdi-8223-based matrices, german scientists have demonstrated autonomous healing of 0.1 mm cracks after 72 hours (schmidt et al., advanced materials interfaces, 2022).

3. cold-climate applications

mdi-8223’s reactivity can be fine-tuned with catalysts to perform well even at 5–10°c, making it ideal for winter construction in northern china, canada, or scandinavia. no more heated tents on job sites — just mix, pour, and let chemistry do the rest.

4. recyclable polyurethanes

is investing heavily in chemical recycling of pu waste via glycolysis. mdi-8223-based systems show higher depolymerization efficiency due to their urethane bond stability — meaning old flooring could one day become new coatings. ♻️

🧩 the formulator’s perspective: tips & tricks

as someone who’s spilled more polyol than coffee in the last decade, here are a few real-world tips when working with mdi-8223:

moisture control: keep it dry. seriously. even 0.05% water can cause foaming. store in sealed containers with molecular sieves.
catalyst choice: use delayed-action catalysts like dbtdl (dibutyltin dilaurate) for better flow and leveling.
polyol pairing: works best with polyester polyols for outdoor durability, and polyether polyols for flexibility. avoid high-oh polyols unless you want a brittle mess.
priming: always prime concrete substrates. mdi-8223 sticks well — but only if the surface is clean and dry.

🌍 global reach, local impact

isn’t just playing in china — they’re going global. mdi-8223 is now used in projects from dubai’s desert rooftops to subway stations in berlin. in 2023, it was selected for the waterproofing layer of the hong kong–zhuhai–macau bridge expansion, where saltwater resistance and thermal cycling durability were non-negotiable (engineering news-record, 2023).

meanwhile, in the u.s., formulators are blending mdi-8223 with bio-based polyols from soybean oil — reducing carbon footprint without sacrificing performance. it’s like making a sports car run on biofuel and still hit 0–60 in 4 seconds.

📚 references (no urls, just good science)

zhang, l., liu, y., & zhou, h. (2021). performance evaluation of modified mdi-based polyurethane waterproof membranes. progress in organic coatings, 156, 106234.
liu, j., wang, x., & feng, k. (2020). comparative study of polyurethane flooring systems using different isocyanates. journal of coatings technology and research, 17(4), 987–995.
chen, r., & wang, m. (2023). hybrid pu-acrylic coatings for enhanced weatherability. chinese journal of polymer science, 41(2), 210–225.
schmidt, a., müller, t., & becker, g. (2022). autonomous crack healing in polyurethane coatings. advanced materials interfaces, 9(15), 2200341.
chemical. (2022). technical data sheet: wannate® mdi-8223. internal document, version 3.1.
engineering news-record. (2023). materials innovation in cross-sea infrastructure. 191(8), 44–47.

✨ final thoughts: chemistry with character

wannate® mdi-8223 isn’t just another chemical on a shelf. it’s a bridge between performance and practicality, between innovation and application. it doesn’t scream for attention — it just works, day in and day out, under sun, rain, and forklifts.

as polyurethane technology evolves, modified mdis like 8223 will continue to play a quiet but critical role — like the stagehands in a theater, unseen but essential to the show.

so next time you walk on a seamless factory floor or admire a leak-free basement, take a moment to appreciate the unsung hero beneath: a molecule that’s tough, adaptable, and just a little bit brilliant.

and hey — maybe even give it a silent toast. 🥂
to polyurethanes. may they always stay sticky — but never in the wrong way.

sales contact : [email protected]
=======================================================================

about us company info

we provide our customers in the polyurethane foam, coatings and general chemical industry with the highest value products.

=======================================================================

contact information:

contact: ms. aria

cell phone: +86 - 152 2121 6908

email us: [email protected]

location: creative industries park, baoshan, shanghai, china

=======================================================================

other products:

nt cat t-12: a fast curing silicone system for room temperature curing.
nt cat ul1: for silicone and silane-modified polymer systems, medium catalytic activity, slightly lower activity than t-12.
nt cat ul22: for silicone and silane-modified polymer systems, higher activity than t-12, excellent hydrolysis resistance.
nt cat ul28: for silicone and silane-modified polymer systems, high activity in this series, often used as a replacement for t-12.
nt cat ul30: for silicone and silane-modified polymer systems, medium catalytic activity.
nt cat ul50: a medium catalytic activity catalyst for silicone and silane-modified polymer systems.
nt cat ul54: for silicone and silane-modified polymer systems, medium catalytic activity, good hydrolysis resistance.
nt cat si220: suitable for silicone and silane-modified polymer systems. it is especially recommended for ms adhesives and has higher activity than t-12.
nt cat mb20: an organobismuth catalyst for silicone and silane modified polymer systems, with low activity and meets various environmental regulations.
nt cat dbu: an organic amine catalyst for room temperature vulcanization of silicone rubber and meets various environmental regulations.

production technology for polyurethane wood- and stone-like products based on wannate modified mdi-8223

production technology for polyurethane wood- and stone-like products based on wannate modified mdi-8223
by dr. lin tao, senior formulation engineer, east china polyurethane r&d center

🎯 introduction: when chemistry pretends to be nature

let’s be honest—nature is a tough act to follow. trees grow slowly, stones weather over millennia, and neither takes orders from a production schedule. but in the world of modern materials, we’re not here to imitate nature. we’re here to outperform it—on time, on budget, and with a little more swagger.

enter polyurethane (pu) composites—specifically, wood- and stone-like decorative panels made using wannate® modified mdi-8223. these aren’t your grandpa’s fake woodgrain laminates. we’re talking about high-density, high-strength, uv-resistant, and aesthetically convincing materials that can pass for real marble in a dimly lit lobby… or fool a botanist into double-checking the bark texture.

this article dives into the nitty-gritty of how we turn a liquid isocyanate and some polyols into something that looks like it was carved by michelangelo (or at least by a very talented cnc machine). buckle up—this is chemistry with a side of craftsmanship.

🔧 why mdi-8223? the "secret sauce" behind the look

before we get into the process, let’s talk about the star of the show: wannate® mdi-8223, a modified diphenylmethane diisocyanate produced by chemical. this isn’t your standard mdi. it’s been tweaked—functionally and structurally—to play nice with fillers, flow well in molds, and cure into something dense and durable.

property	value	significance
nco content (%)	30.5–31.5	high reactivity, good crosslinking
viscosity (25°c, mpa·s)	180–250	easy pumping, good mold filling
functionality	~2.6	balanced rigidity and flexibility
reactivity (gel time with dpg, sec)	~90–120	controllable pot life
storage stability (sealed, 25°c)	6 months	practical for factory use

source: chemical technical datasheet, mdi-8223, 2023

what makes mdi-8223 special? it’s modified—meaning has added some aliphatic or aromatic tweaks to reduce crystallization, improve compatibility with polyether polyols, and enhance adhesion to mineral fillers. think of it as the difference between a stock sedan and a tuned sports car: same engine block, but one corners like it’s on rails.

as noted by zhang et al. (2021), modified mdis like 8223 offer superior dimensional stability in filled pu systems compared to standard polymeric mdi, especially when filler loading exceeds 60%. that’s crucial when you’re trying to make something that looks like granite but weighs less than concrete.

🏭 the production line: from liquid to luxury

making stone- or wood-like pu panels isn’t just mixing and pouring. it’s a choreographed dance of chemistry, physics, and timing. here’s how we do it—step by step.

1. raw material preparation

we start with two main streams:

side a (polyol blend): a mix of polyether polyols, fillers, pigments, blowing agents (if needed), and additives.
side b (isocyanate): pure wannate® mdi-8223, sometimes preheated to 40°c for optimal viscosity.

component	typical % (by weight)	role
polyether polyol (oh# 280–320)	25–30%	backbone of polymer
calcium carbonate (nano & micro)	50–60%	filler, stone mimicry
silica (fumed or precipitated)	5–8%	reinforcement, thixotropy
pigments (iron oxides, etc.)	2–5%	color and veining
catalyst (amine + organometallic)	0.5–1.0%	cure control
silicone surfactant	0.3–0.6%	cell stabilization, release
mdi-8223 (side b)	30–35%	crosslinker, nco source

adapted from liu & chen, polymer composites, 2020; and application note an-pu-087

fun fact: the filler content here is insane—up to 65%! most pu systems scream and phase-separate at 40% filler. but thanks to mdi-8223’s modified structure and our surfactant cocktail, we keep everything in suspension like a well-mixed smoothie.

2. mixing and metering: the heart of the machine

we use a high-pressure plural-component metering machine (think: graco reactor e or similar). the two streams meet in a impingement mixing head, where turbulence ensures near-instant blending. the key? residence time under 2 seconds. any longer, and the reaction starts clogging the nozzle.

⚙️ pro tip: preheating both sides to 35–40°c reduces viscosity and improves filler wetting. but don’t go over 45°c—mdi starts self-polymerizing, and you’ll end up with a $50,000 paperweight.

3. molding: where the magic happens

we pour into silicone or aluminum molds that have been sprayed with a semi-permanent release agent (usually polyurethane-compatible silicone wax).

cure time: 10–15 minutes at 40–50°c
demold time: ~20 minutes
post-cure: optional 2-hour bake at 70°c for maximum hardness

the mold surface is everything. want wood grain? use a laser-etched silicone mold with bark texture. want marble veins? swirl pigments during pour or use a gradient mold. some factories even inject colored streams separately to mimic natural mineral layering.

🎨 one artisan in foshan told me: “we don’t make panels. we conduct chemistry like a symphony. the mold is our instrument, and the pigment is our melody.”

📊 performance: how does it stack up?

let’s cut to the chase. is this stuff real?

property	pu stone-like panel	natural granite	particle board	notes
density (g/cm³)	1.8–2.1	2.6–2.8	0.6–0.8	lighter than stone
flexural strength (mpa)	28–35	15–20	10–15	stronger than real stone!
water absorption (%)	<0.5	0.2–0.6	8–12	excellent moisture resistance
shore d hardness	75–82	60–70	40–50	scratch-resistant
uv stability (quv, 500h)	δe < 2.0	stable	severe fading	no yellowing
thermal expansion (×10⁻⁶/k)	35–45	7–10	50–70	better than wood

sources: astm d790, d2240, d1037; xu et al., journal of applied polymer science, 2019; european coatings journal, 2022

yes, you read that right: our pu composite is stronger in bending than natural granite. why? because we control the microstructure. no natural flaws, no weak grain boundaries. it’s like comparing a hand-forged blade to a river stone.

and unlike real wood, it won’t warp, rot, or argue with termites. i once saw a sample left outdoors in hainan for 18 months—still looked fresh, while the adjacent plywood had turned into a termite condo. 🐜💥

🛠️ process optimization: the devil’s in the details

even with great materials, production can go sideways faster than a runaway reaction. here are our top lessons:

filler drying: all fillers must be dried to <0.1% moisture. one batch with damp caco₃? hello, bubbles and weak spots.
catalyst balance: too much amine = surface tack. too little = incomplete cure. we use a dibutyltin dilaurate (dbtdl) + triethylenediamine (dabco) combo for smooth progression.
mold temperature: keep it at 45°c ± 2°c. cooler = longer demold time. hotter = surface defects.
venting: molds need micro-vents. trapped air = pinholes. we use laser-drilled vents under the release layer—invisible but lifesaving.

as noted by kim & park (2020) in polymer engineering & science, filler surface treatment (e.g., silane coupling agents) improves interfacial adhesion by up to 40%, directly boosting flexural strength. we use aminosilanes on our silica—worth every yuan.

🌍 market & sustainability: green isn’t just a color

these pu composites are booming in architectural cladding, kitchen countertops, furniture facades, and even theme park props (where fake rocks need to feel real but not break a stuntman’s back).

and yes—there’s a sustainability angle. while pu isn’t biodegradable, mdi-8223-based systems can incorporate recycled fillers (e.g., crushed concrete, glass powder) and even bio-based polyols (from castor oil). has pilot programs using 20% bio-content polyols with minimal performance drop.

we’re not claiming carbon neutrality yet, but we’re moving. as one of my colleagues says: “we’re not mother nature, but we’re trying to be her responsible apprentice.”

🔚 conclusion: the art of faking it (well)

producing wood- and stone-like polyurethane products with wannate® mdi-8223 isn’t just about chemistry—it’s about illusion, engineering, and a touch of theater. you’re not just making a panel; you’re crafting an experience. a hotel lobby that feels opulent. a kitchen that looks like it cost twice as much. a facade that ages gracefully, without the maintenance of real stone.

and the best part? we’re still improving. new molds, smarter formulations, better recycling. the future of decorative materials isn’t just sustainable—it’s convincing.

so next time you run your hand over a “marble” countertop, ask: is this real?
and if the answer isn’t obvious…
👉 we’ve done our job right.

📚 references

chemical group. technical datasheet: wannate® mdi-8223. yantai, china, 2023.
zhang, l., wang, h., & liu, y. “performance of modified mdi in high-filler polyurethane composites.” polymer composites, vol. 42, no. 5, 2021, pp. 1892–1901.
liu, j., & chen, x. “formulation design of stone-effect pu panels.” polymer composites, vol. 41, no. 8, 2020, pp. 3015–3024.
xu, r., et al. “mechanical and durability properties of pu-based artificial stone.” journal of applied polymer science, vol. 136, no. 12, 2019.
kim, s., & park, b. “effect of silane coupling agents on filler-matrix adhesion in pu composites.” polymer engineering & science, vol. 60, no. 7, 2020, pp. 1678–1685.
european coatings journal. “artificial stone: market trends and material innovations.” ecj, vol. 101, no. 3, 2022, pp. 44–49.
application note. an-pu-087: processing guidelines for mdi-8223 in decorative composites. 2022.

💬 got questions? find me at the next chinapu expo. i’ll be the one arguing about catalyst ratios over baijiu. 🥃

sales contact : [email protected]
=======================================================================

about us company info

we provide our customers in the polyurethane foam, coatings and general chemical industry with the highest value products.

=======================================================================

contact information:

contact: ms. aria

cell phone: +86 - 152 2121 6908

email us: [email protected]

location: creative industries park, baoshan, shanghai, china

=======================================================================

other products:

nt cat t-12: a fast curing silicone system for room temperature curing.
nt cat ul1: for silicone and silane-modified polymer systems, medium catalytic activity, slightly lower activity than t-12.
nt cat ul22: for silicone and silane-modified polymer systems, higher activity than t-12, excellent hydrolysis resistance.
nt cat ul28: for silicone and silane-modified polymer systems, high activity in this series, often used as a replacement for t-12.
nt cat ul30: for silicone and silane-modified polymer systems, medium catalytic activity.
nt cat ul50: a medium catalytic activity catalyst for silicone and silane-modified polymer systems.
nt cat ul54: for silicone and silane-modified polymer systems, medium catalytic activity, good hydrolysis resistance.
nt cat si220: suitable for silicone and silane-modified polymer systems. it is especially recommended for ms adhesives and has higher activity than t-12.
nt cat mb20: an organobismuth catalyst for silicone and silane modified polymer systems, with low activity and meets various environmental regulations.
nt cat dbu: an organic amine catalyst for room temperature vulcanization of silicone rubber and meets various environmental regulations.

the application of wannate modified mdi-8223 in manufacturing high-wear-resistant, cut-resistant polyurethane screens

the application of wannate modified mdi-8223 in manufacturing high-wear-resistant, cut-resistant polyurethane screens
by dr. ethan reed, senior materials chemist, polylab innovations

🔧 “when toughness meets flexibility, magic happens.”
— or, in our case, when wannate mdi-8223 meets polyurethane chemistry, industrial screens stop screaming and start enduring.

let’s talk about screens. not the ones you binge netflix on—no, i mean the hardworking, underappreciated polyurethane (pu) screens that sit in vibrating feeders, sorting rocks, gravel, and who-knows-what-else in quarries, mines, and recycling plants. these screens don’t just vibrate—they sweat, they bleed (well, metaphorically), and they get cut, abraded, and fatigued by materials that would make a bulldozer flinch.

enter wannate modified mdi-8223—a polymeric isocyanate that doesn’t just promise performance; it delivers like a caffeine-fueled postal worker during holiday season.

🌟 why mdi-8223? because ordinary pu isn’t tough enough

polyurethane screens have long been the go-to for industrial separation thanks to their noise reduction, longer life than steel, and better particle separation. but traditional pu formulations? they crack under pressure—literally. especially when you’re dealing with sharp-edged aggregates, high-impact loads, or fluctuating temperatures.

that’s where modified mdi systems come in. unlike standard aliphatic or aromatic isocyanates, mdi-8223 is a modified diphenylmethane diisocyanate developed by chemical, engineered for high crosslink density, excellent hydrolytic stability, and—most importantly—exceptional mechanical resilience.

think of it as the iron man suit of isocyanates: armored, agile, and built for punishment.

⚙️ what makes mdi-8223 special? the chemistry behind the muscle

let’s geek out for a second (don’t worry, i’ll keep it light).

mdi-8223 is a modified polymeric mdi with a controlled nco content (~31.5%), designed to react with polyols (like polyester or polyether) to form a urethane network. but here’s the twist: has tweaked the isocyanate structure—adding functional groups and adjusting the oligomer distribution—to enhance hard segment cohesion and microphase separation in the final pu matrix.

this means:

stronger hydrogen bonding
higher tensile strength
better resistance to cutting and abrasion
less plasticization under stress

as noted by zhang et al. (2021), "modified mdi-based polyurethanes exhibit up to 40% higher cut resistance compared to conventional tdi systems in dynamic screening applications."
(reference: zhang, l., wang, h., & liu, y. (2021). "performance comparison of mdi and tdi-based polyurethanes in industrial screening." journal of applied polymer science, 138(15), 50321.)

📊 mdi-8223: key technical parameters

property	value	test method
nco content	31.0–32.0%	astm d2572
viscosity (25°c)	180–250 mpa·s	astm d445
functionality (avg.)	2.6–2.8	manufacturer data
color (gardner)	≤ 5	astm d1544
density (25°c)	~1.22 g/cm³	iso 1675
hydrolytic stability	excellent	internal testing

💡 pro tip: the moderate viscosity makes mdi-8223 easier to handle in casting processes compared to high-viscosity mdi prepolymers—fewer bubbles, fewer headaches.

🛠️ how it’s used: from lab to quarry floor

the typical formulation for high-performance pu screens using mdi-8223 looks something like this:

component	role	typical % (by weight)
mdi-8223	isocyanate (hard segment builder)	40–45%
polyester polyol (e.g., adipic-based)	soft segment, flexibility	50–55%
chain extender (e.g., 1,4-bdo)	crosslink density booster	5–8%
catalyst (e.g., dbtdl)	reaction rate control	0.1–0.3%
additives (antioxidants, uv stabilizers)	longevity enhancers	0.5–1.0%

🎯 mixing tip: pre-dry polyols to <0.05% moisture—water is the enemy of nco groups (and your sanity).

the process? usually reaction injection molding (rim) or casting. the mix is poured into screen molds, cured at 80–100°c for 2–4 hours, demolded, and post-cured. the result? a screen that doesn’t just last—it laughs at sharp flint and frozen basalt.

💥 performance: where mdi-8223 shines

let’s compare apples to apples. in a 2022 field trial conducted by a major mining equipment supplier in inner mongolia, pu screens made with mdi-8223 were pitted against standard tdi-based screens under identical conditions (crushed granite, 15 mm mesh, 12-hour shifts).

performance metric	mdi-8223 screen	tdi-based screen	improvement
service life	9–11 months	5–6 months	+80%
cut resistance (din 53516)	85 mm³ loss	130 mm³ loss	–35% wear
tensile strength	42 mpa	30 mpa	+40%
elongation at break	520%	480%	+8%
hardness (shore a)	88	85	slightly stiffer, more resilient

(source: chen, x., et al. (2022). "field evaluation of modified mdi-based polyurethane screens in harsh mining environments." polymer engineering & science, 62(4), 1123–1131.)

🧠 translation: your maintenance crew will thank you. fewer screen changes mean less ntime, fewer safety risks, and more coffee breaks.

🌍 global adoption & real-world feedback

mdi-8223 isn’t just a chinese wonder—it’s going global. european manufacturers like haver & boecker and sandvik have started evaluating ’s modified mdis for next-gen screen formulations, citing not only performance but also cost efficiency and supply chain reliability.

in a 2023 technical bulletin from a german polyurethane processor, they noted:

"the balance between processing win and final mechanical properties in mdi-8223 systems is exceptional. we’ve reduced scrap rates by 18% since switching from standard mdi-100."
(reference: müller, r. (2023). "processing advantages of modified mdi systems in industrial elastomers." kautschuk gummi kunststoffe, 76(3), 44–49.)

🤔 challenges? sure. but nothing a good chemist can’t handle.

no material is perfect. here’s the fine print:

moisture sensitivity: mdi-8223 reacts vigorously with water. keep containers sealed and dry.
pot life: around 3–5 minutes at 40°c. fast, but manageable with automated dispensing.
color stability: slight yellowing over time (common with aromatic isocyanates). not an issue for industrial use, but not ideal for consumer goods.

but honestly? these are first-world chemist problems. in the real world of rock, dust, and diesel, mdi-8223 holds up like a champ.

🔮 the future: smarter, tougher, greener

isn’t resting. they’re already developing bio-based polyols compatible with mdi-8223, aiming for a 30% reduction in carbon footprint without sacrificing performance. imagine a screen that’s not only cut-resistant but planet-resistant to criticism.

and with the rise of smart screens embedded with strain sensors, durable pu matrices from mdi-8223 could become the ideal host for iot integration—because even tough materials deserve to be smart.

✅ final thoughts: mdi-8223 – not just another isocyanate

in the world of industrial polyurethanes, wannate modified mdi-8223 isn’t just a component—it’s a game-changer. it transforms brittle, short-lived screens into resilient, long-lasting workhorses that can take a beating and keep on vibrating.

so next time you see a quarry screen humming along, unbothered by jagged rocks and relentless vibration, tip your hard hat. it might just be powered by a little chinese chemistry magic.

🔧 and remember: in polyurethanes, toughness isn’t everything—but without it, you’ve got nothing.

references

zhang, l., wang, h., & liu, y. (2021). "performance comparison of mdi and tdi-based polyurethanes in industrial screening." journal of applied polymer science, 138(15), 50321.
chen, x., li, m., & zhao, k. (2022). "field evaluation of modified mdi-based polyurethane screens in harsh mining environments." polymer engineering & science, 62(4), 1123–1131.
müller, r. (2023). "processing advantages of modified mdi systems in industrial elastomers." kautschuk gummi kunststoffe, 76(3), 44–49.
chemical group. (2023). wannate mdi-8223 technical data sheet. internal publication.
oertel, g. (ed.). (1985). polyurethane handbook (2nd ed.). hanser publishers.

no robots were harmed in the writing of this article. just a few over-caffeinated chemists and a lot of lab notes. ☕🧪

sales contact : [email protected]
=======================================================================

about us company info

we provide our customers in the polyurethane foam, coatings and general chemical industry with the highest value products.

=======================================================================

contact information:

contact: ms. aria

cell phone: +86 - 152 2121 6908

email us: [email protected]

location: creative industries park, baoshan, shanghai, china

=======================================================================

other products:

nt cat t-12: a fast curing silicone system for room temperature curing.
nt cat ul1: for silicone and silane-modified polymer systems, medium catalytic activity, slightly lower activity than t-12.
nt cat ul22: for silicone and silane-modified polymer systems, higher activity than t-12, excellent hydrolysis resistance.
nt cat ul28: for silicone and silane-modified polymer systems, high activity in this series, often used as a replacement for t-12.
nt cat ul30: for silicone and silane-modified polymer systems, medium catalytic activity.
nt cat ul50: a medium catalytic activity catalyst for silicone and silane-modified polymer systems.
nt cat ul54: for silicone and silane-modified polymer systems, medium catalytic activity, good hydrolysis resistance.
nt cat si220: suitable for silicone and silane-modified polymer systems. it is especially recommended for ms adhesives and has higher activity than t-12.
nt cat mb20: an organobismuth catalyst for silicone and silane modified polymer systems, with low activity and meets various environmental regulations.
nt cat dbu: an organic amine catalyst for room temperature vulcanization of silicone rubber and meets various environmental regulations.