Hey, if you're knee-deep in lab work where things get seriously hot, our Cr10Ni90 Nichrome Bar is the go-to solution that's been keeping experiments running smooth at DLX Company. Picture this: a tough-as-nails alloy bar that's basically built for those high-stakes heating setups in laboratories. We're talking about a material that's 10% chromium and a whopping 90% nickel, designed to crank up the heat without breaking a sweat—or in this case, without oxidizing or corroding away.
For more details, pls directly contact us.
At DLX, we've honed this product over years of tweaking and testing, making sure every bar we ship out is ready to handle the demands of modern lab heating systems. Whether you're firing up a furnace for material synthesis or need steady temps for thermal analysis, our Cr10Ni90 Nichrome Bar delivers consistent performance. It heats fast, resists wear like a champ, and stays stable even when you're pushing temperatures close to 1200°C. No more worrying about breakdowns mid-experiment; this bar's got your back with its high electrical resistivity that turns electrical current into reliable, even heat every time.
What sets it apart? That high nickel content isn't just for show—it's what gives it killer corrosion resistance, perfect for labs dealing with funky chemicals or humid conditions. We've seen it shine in everything from research reactors to precision ovens, where other materials might flake out. And let's be real, in the lab world, reliability means everything. Our bars are precision-rolled, annealed for uniformity, and cut to your specs, so integration into your heating systems is a breeze. If you're searching for "high-temperature Nichrome bar for labs" or "Cr10Ni90 alloy solutions," you've landed in the right spot—DLX makes sure you get quality that lasts.
Performance / material | Cr10Ni90 | Cr20Ni80 | Cr15Ni60 | Cr20Ni35 | Cr20Ni30 | ||
Composition | Ni | 90 | Rest | Rest | 55.0~61.0 | 34.0~37.0 | 30.0~34.0 |
Cr | 10 | 20.0~23.0 | 28.0~31.0 | 15.0~18.0 | 18.0~21.0 | 18.0~21.0 | |
Fe | -- | ≤1.0 | ≤1.0 | Rest | Rest | Rest | |
Maximum temperature℃ | 1300 | 1200 | 1250 | 1150 | 1100 | 1100 | |
Meltiing point ℃ | 1400 | 1400 | 1380 | 1390 | 1390 | 1390 | |
Density g/cm3 | 8.7 | 8.4 | 8.1 | 8.2 | 7.9 | 7.9 | |
Resistivity at 20℃ (μΩ·m) | -- | 1.09±0.05 | 1.18±0.05 | 1.12±0.05 | 1.00±0.05 | 1.04±0.05 | |
Elongation at rupture | ≥20 | ≥20 | ≥20 | ≥20 | ≥20 | ≥20 | |
Specific heat (J/g.℃) | -- | 0.44 | 0.461 | 0.494 | 0.5 | 0.5 | |
Thermal conductivity (KJ/m.h℃) | -- | 60.3 | 45.2 | 45.2 | 43.8 | 43.8 | |
Coefficient of lines expansion a×10-6/(20~1000℃) | -- | 18 | 17 | 17 | 19 | 19 | |
Micrographic structure | -- | Austenite | Austenite | Austenite | Austenite | Austenite | |
Magnetic properties | -- | Non-magnetic | Non-magnetic | Non-magnetic | Weak magnetic | Weak magnetic | |
Shape | Size (mm) |
Wire | 0.05-7.5 |
Rod | 8-50 |
Ribbon | (0.05-0.35)*(0.5-6.0) |
Strip | (0.5-2.5)*(5-40) |
For more details, pls directly contact us.
Now, let's chat about the bigger picture: the industry around high-temperature alloys like our Cr10Ni90 Nichrome Bar. The lab heating sector is buzzing right now, and it's all about pushing boundaries in precision and efficiency. Back in the day, heating elements were clunky and prone to failure, but with advancements in alloy tech, we're seeing a boom in applications that demand exact control. Think about the global push for R&D in materials science—labs worldwide are cranking out innovations in batteries, semiconductors, and biotech, all relying on stable heat sources.
From what we've observed at DLX, the trends are leaning hard toward sustainability and miniaturization. Energy costs are climbing, so everyone's eyeing alloys that heat quicker with less power draw. Our Cr10Ni90 fits right in, offering that fast ramp-up time that cuts down on wait periods and saves juice. There's also this wave of green lab tech; regulations are tightening on emissions, and materials like ours help by running cleaner—no nasty byproducts from oxidation. Market-wise, the demand for Nichrome-based products is skyrocketing—projections show the high-temperature alloys market growing at over 5% annually through 2030, fueled by expansions in pharma and electronics testing.
But it's not all smooth sailing. Supply chain hiccups with nickel prices can fluctuate, but DLX stays ahead by sourcing smart and stocking deep, so you never miss a beat. We're seeing more integration with smart controls too—IoT-enabled heating systems where our bars provide the backbone for automated temp management. In chemical and materials labs, the trend is toward corrosion-resistant setups for safer, longer-lasting equipment. Overall, the industry's evolving to be more efficient and eco-friendly, and DLX is right there leading the charge with products engineered for tomorrow's challenges.
Diving into applications, our Cr10Ni90 Nichrome Bar really flexes its muscles in high-temperature laboratory heating systems. Start with furnaces: these bad boys are the heart of any materials testing lab. You need to simulate extreme conditions for alloy development or polymer curing? Our bar forms the heating element that gets you there reliably, holding steady at 1000°C+ without warping. In chemical reactors, where reactions need precise heat to avoid side products, the bar's oxidation resistance keeps things pure and uncontaminated.
We've supplied tons to thermal analysis setups, like differential scanning calorimeters, where even tiny temp swings can ruin data. The bar's ductility makes it easy to shape into coils or straight rods, fitting snugly into compact lab gear. And don't sleep on its role in vacuum ovens or annealing chambers—high nickel means it laughs off corrosive vapors that would eat through lesser alloys. For biotech labs pushing into high-temp sterilization or enzyme studies, it's a game-changer, ensuring uniform heating without hotspots.
At DLX, we pride ourselves on customizing these bars for specific lab needs, whether it's a small-scale research rig or a full industrial sim. The result? Faster experiments, fewer failures, and data you can trust. If you're optimizing your lab for "Nichrome bar heating applications," our product streamlines it all.
When it comes to standing out in this crowded field, DLX Company doesn't just compete—we dominate with advantages that make our Cr10Ni90 Nichrome Bar the smart pick. Sure, there are other players out there offering similar alloys, but let's break down why we edge them out, especially for lab pros who can't afford downtime.
First off, our quality control is next-level. Every batch undergoes rigorous testing for resistivity uniformity and high-temp endurance, hitting specs like 1.10 μΩ·m resistivity and 1200°C max without variance. Competitors might cut corners on purity, leading to inconsistent heating, but DLX uses premium sourcing to deliver bars that perform predictably, experiment after experiment. That means less recalibration and more focus on your research.
Then there's our corrosion edge. With 90% nickel, our bar shrugs off acidic fumes or oxidative stress better than most, extending service life by up to 30% in harsh lab environments. We've heard stories from users switching to us after dealing with frequent replacements elsewhere—our stuff just lasts. Plus, we're all about customization; need a specific diameter or length for your heating coil? We tailor it fast, with lead times that beat the industry average.
Sustainability? DLX leads here too. Our manufacturing cuts energy use in alloying by 15% through efficient vacuum processes, aligning with green lab initiatives. And while others might jack up prices with nickel volatility, we stabilize costs through smart hedging, keeping your budget steady. Finally, our support seals the deal—technical advice from our engineers ensures seamless integration, something generic suppliers often skimp on.
In short, choosing DLX means reliability, innovation, and value that propels your lab forward. We've built our rep on delivering Cr10Ni90 Nichrome Bars that don't just meet standards—they exceed them, giving you the confidence to tackle the toughest high-temperature challenges.
About Us:
Our 12,000㎡ factory is equipped with complete capabilities for research, production, testing, and packaging. We strictly adhere to ISO 9001 standards in our production processes, with an annual output of 1,200 tons. This ensures that we meet both quantity and quality demands. Furthermore, all products undergo rigorous simulated environment testing including high temperature, high pressure, and corrosion tests before being dispatched, ensuring they meet customer specifications.
For all our clients, we offer timely and multilingual after-sales support and technical consulting, helping you resolve any issues swiftly and efficiently.
Client Visits
Building Stronger Partnerships
We support all kinds of testing:
FAQs
Q1: What is the composition of Cr10Ni90 Nichrome Bar?
A: Cr10Ni90 Nichrome Bar is an alloy primarily made up of 10% chromium (Cr) and 90% nickel (Ni), with possible trace elements for enhanced properties, offering excellent corrosion resistance and high-temperature stability.
Q2: What are the key material properties of this Nichrome Bar?
A: It features high electrical resistivity around 1.08-1.13 μΩ·m, maximum operating temperature up to 1200°C, excellent oxidation resistance due to a protective chromium oxide layer, and good mechanical strength with tensile strength over 600 MPa.
Q3: What are the main applications of Cr10Ni90 Nichrome Bar in laboratory heating systems?
A: It's widely used in high-temperature heating elements for lab furnaces, ovens, and reactors, providing reliable heat generation for experiments in materials testing, chemical analysis, and thermal processing.
Q4: How does Cr10Ni90 Nichrome Bar perform in corrosive environments?
A: Thanks to its high nickel content, it offers superior corrosion resistance in acidic or oxidative conditions, making it ideal for lab systems exposed to harsh chemicals or humid atmospheres.
Q5: What are the current industry trends for Nichrome alloys like Cr10Ni90?
A: Trends include a shift toward high-performance, miniaturized designs for energy-efficient lab equipment, increased use in sustainable green tech applications, and rising demand due to advancements in precision heating for R&D.
Q6: How is Cr10Ni90 Nichrome Bar manufactured?
A: It's produced by melting high-purity nickel and chromium in a vacuum furnace, followed by casting, rolling into bars, and annealing for uniform properties, ensuring consistency for lab use.
Q7: What maintenance is required for heating systems using this bar?
A: Regular inspection for oxidation buildup, proper electrical connections to avoid hotspots, and operation within 1200°C limits to maintain longevity, typically lasting years in lab settings.
Q8: Why choose Cr10Ni90 over other alloys for lab heating?
A: It provides faster heating response and better flavor neutrality in specialized uses, combined with unmatched stability at extreme temperatures, outperforming standard alloys in precision lab environments.