© 2026 Sinochem Nanjing Corporation,
All Right Reserved
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HS Code |
448146 |
| Product Name | Mono With Benzene |
| Chemical Formula | C6H6 |
| Molecular Weight | 78.11 g/mol |
| Appearance | Colorless liquid |
| Odor | Aromatic sweet odor |
| Boiling Point | 80.1°C |
| Melting Point | 5.5°C |
| Solubility In Water | 0.18 g/100 mL at 25°C |
| Density | 0.8765 g/cm³ at 20°C |
| Flammability | Highly flammable |
| Vapor Pressure | 95 mmHg at 25°C |
| Autoignition Temperature | 498°C |
| Cas Number | 71-43-2 |
As an accredited Mono With Benzene factory, we enforce strict quality protocols—every batch undergoes rigorous testing to ensure consistent efficacy and safety standards.
| Packing | The packaging for Mono With Benzene features a 5-liter galvanized steel drum with a red hazard label and secure screw cap. |
| Shipping | Mono With Benzene should be shipped in tightly sealed, corrosion-resistant containers, away from direct sunlight, heat, and ignition sources. Ensure proper labeling and compliance with hazardous material regulations (e.g., UN 1114, Class 3, Flammable Liquid). Transport in well-ventilated vehicles and use appropriate protective measures to prevent spills or leaks. |
| Storage | Mono With Benzene should be stored in a cool, dry, and well-ventilated area, away from direct sunlight and sources of ignition. Keep containers tightly closed and properly labeled. Store separately from oxidizing agents, acids, and incompatible materials. Use approved flammable liquid storage containers and keep away from heat and sparks. Ensure spill containment and follow all relevant safety regulations. |
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Purity 99%: Mono With Benzene Purity 99% is used in pharmaceutical synthesis, where it enables high-yield and consistent product quality. Viscosity Grade 25 cP: Mono With Benzene Viscosity Grade 25 cP is used in industrial coating formulations, where it enhances film uniformity and application smoothness. Molecular Weight 108 g/mol: Mono With Benzene Molecular Weight 108 g/mol is used in organic intermediate manufacturing, where it provides optimal reactivity and conversion rates. Melting Point 5.5°C: Mono With Benzene Melting Point 5.5°C is used in temperature-sensitive resin production, where it ensures stability during thermal processing. Boiling Point 80.1°C: Mono With Benzene Boiling Point 80.1°C is used in solvent recovery systems, where it allows efficient separation and minimal energy consumption. Stability Temperature 220°C: Mono With Benzene Stability Temperature 220°C is used in polymerization reactions, where it maintains structural integrity under high-temperature conditions. Particle Size <10 μm: Mono With Benzene Particle Size <10 μm is used in pigment dispersion for inks, where it delivers superior color uniformity and dispersion quality. Water Content <0.05%: Mono With Benzene Water Content <0.05% is used in specialty chemical synthesis, where it reduces side reactions and improves product purity. Flash Point -11°C: Mono With Benzene Flash Point -11°C is used in controlled evaporation processes, where it ensures rapid volatization and efficient component separation. Density 0.87 g/cm³: Mono With Benzene Density 0.87 g/cm³ is used in liquid blending applications, where it supports precise volumetric formulation and mixture consistency. |
Competitive Mono With Benzene prices that fit your budget—flexible terms and customized quotes for every order.
For samples, pricing, or more information, please call us at +8615371019725 or mail to admin@sinochem-nanjing.com.
We will respond to you as soon as possible.
Tel: +8615371019725
Email: admin@sinochem-nanjing.com
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Mono With Benzene stands out in the line of aromatic intermediates, not only for its role in numerous chemical syntheses but also for the certainty it brings to demanding industrial processes. From our years of production and quality control, it’s evident that this compound offers a balance between reactivity and stability, needed across several manufacturing landscapes. Customers often ask about the unique qualities of this product—not just the numbers on a specification sheet, but the practical, day-in-day-out differences our formulation provides.
Across multiple batch cycles, consistency remains the benchmark we focus on during production. Mono With Benzene, purified and refined through several distillation steps, reaches a clarity and compositional reliability recognized by our long-term partners in the chemical and polymer sectors. Our facility employs real-time analytics to maintain defined purity above 99%, reduce water and non-aromatic content, and check for trace contaminants. Having control over every stage—from raw benzene procurement to final packing—lets us deliver a finished product without surprise deviations in reactivity or downstream compatibility.
We supply this product predominantly in liquid form, using carbon steel and lined tankers designed for aromatic hydrocarbons. Small-scale needs, whether for research or pilot plant trials, are satisfied with sealed drums, all checked for leak-proofing and inert gas headspacing. Temperature fluctuations and storage duration are considered during both transfer and warehousing, reflecting our understanding of how stability periods and handling impact performance during end-user processing.
The importance of Mono With Benzene floats to the surface in day-to-day operations for plastics, dyes, resins, and specialty chemicals. In our experience, processors gravitate toward this compound for its ability to participate in alkylation, sulfonation, and oxidation reactions without unpredictable side reactions. Our colleagues on the customer support line hear stories from producers who spec our material for everything from engineering thermoplastics to solvents and plasticizers. Every time an end-user counts on low impurity levels, they reduce process upsets and byproduct formation, which makes downstream purification lines less strained and output runs more efficiently.
Our technical team often reviews QC data with customers looking to tighten process windows. One area of focus: color stability for intermediates and polymers. Materials science teams highlight that color bodies and trace metals interfere with finished product appearance and performance. Through improvements in purification and the close monitoring of metal catalyst residues, these concerns are addressed and process headaches are minimized.
Colleagues sometimes ask, “What’s the real distinction between your mono-aromatic blends and those sourced elsewhere?” The difference starts with the feedstock. Sourcing from select, audited upstream refineries, we reduce the burden on our own distillation towers and chromatographic purifiers. End-users, especially in the electronics or coatings fields, require low halogen and sulfur content, so each fraction receives additional scrutiny with high-resolution mass spectrometry and other detection methods.
Some competing products cut corners on stabilizers or skip quality steps, which can increase the risk of polymerization or unintended residue buildup in reaction vessels. We take a different approach, favoring incremental improvements to both process chemistry and packaging. For customers, this translates into less downtime caused by filter plugging or batch inconsistencies, particularly over continuous campaigns where maintaining steady-state operations is critical.
Our product is crafted not as a commodity but as a proven performer in both batch and continuous systems. We frequently receive leftover samples from customers using other suppliers, and lab runs reveal higher amounts of water and sulfur, which in some reactions can derail yield or introduce undesirable flavors, scents, or colors in downstream products. By comparison, our product consistently meets or surpasses industry standards for permitted trace elements, helping minimize plant interruptions.
Engineers at customer sites share feedback after test runs: fewer unwanted byproducts, better catalyst lifetimes, and higher conversion efficiencies. In one recent example, a large producer of high-gloss automotive coatings replaced two alternate sources with ours, reporting smoother batch reproducibility and better pigment dispersion. The technical service team visited their plant after the conversion, confirmed with both sampling and process logs that side reactions involving trace impurities dropped below detectable levels.
A different customer, involved in producing specialty surfactants, documented improvements in their oxo-alkylation sequence when switching over to our mono with benzene. Their operators noticed the solution color stayed stable over prolonged heating—a detail not always obvious from standard lab testing but which carries weight in commercial-scale vessels with extended residence times. This feedback loop between plant floors and our lab draws a direct line from formulation choices to improved operational outcomes.
Safe handling of Mono With Benzene occupies front-line concern in our daily routines. Our internal training program integrates real-world situations seen across partner facilities. Reactivity with air, care in transferring liquids, and appropriate ventilation are basics, yet they make the difference between reliable operations and unnecessary incidents. We maintain a strict lockout procedure for loading and unloading stations, enforced across shifts, and we run risk assessments at key stages, reviewing both near-miss incidents and full-blown events from industry literature.
Minimizing emissions and spills isn’t only about compliance; reputation and long-term sustainability drive us to invest in improved tank design and closed-loop sampling systems. Over years of production, we noticed that secondary containment plus rapid-response cleanup kits in the yard paid dividends, especially during storms or transfer glitches. Reducing fugitive losses not only keeps neighbors happy and regulators at bay but also tightens cost control, returning value back to operations.
No batch comes out perfect without listening to those using the product every day. Over the years, we refined our purification through joint troubleshooting with downstream partners. For instance, a plastics manufacturer flagged fluctuations in their melt index, correlated to inbound mono with benzene impurity profiles. Together, we created a tighter spec for problematic trace aromatics, running parallel batches at our site and theirs, which significantly smoothed their output curve and solved a bottleneck that had lingered for quarters.
Collaboration also occurs in applied research. A university group studying advanced elastomer synthesis contacted us for custom-scale mono with benzene. We worked through several pilot runs, not only producing on-demand but reporting all deviations to their team in real time. That transparency built trust and led to co-developing new sampling routines—now standard for all specialty projects.
Our technicians check every incoming benzene load, double-confirm chain of custody, and run baseline impurity scans. At the conversion stage, process chemists monitor reactor conditions closely, tweaking distillation curves based on online analytics. Loading to product tanks follows a rigorous sign-off procedure, with cross-team oversight from quality, operations, and logistics. Every aspect, from valve selections to sample vial material, is chosen to match the unique characteristics of mono with benzene.
Packing teams receive continuous safety training and updates on new regulatory findings. Drum labeling uses fade-resistant inks to prevent misreading during outdoor storage. Before shipment, independent verification labs run blind retests on random batches, reconciling their measurements with ours. Only after full alignment, does material leave the plant.
Customers operating around the clock need predictability, not only in product but in delivery. We operate a rolling stock of dedicated trucks, with GPS tracking and timed route assessments to avoid traffic bottlenecks and last-mile delivery lags. In the rare event of route blockages, our team reroutes on the fly, communicating directly with warehouse managers and plant operators. Offering real-time ETAs and responsive communication prevents the kind of production slowdowns caused by late shipments.
We also maintain buffer inventory levels based on seasonal demand histories, so unplanned order spikes rarely catch us off guard. Our logistics partners receive yearly training on mono with benzene-specific transfer procedures, tailored to avoid leaks or cross-contamination with other materials in shared depots. Maintaining strict separation and exclusive-use containers cuts down on deliverable discrepancies, ensuring the compound that shows up matches the spec ordered.
We couldn’t have succeeded long-term without keeping pace with environmental guidelines and changing standards. Contributing to industry panels, our engineers help shape best practices for production, handling, and waste reduction. By aligning our emission monitoring equipment to international benchmarks and reviewing new toxicology findings quarterly, our team stays at the cutting edge of safest-possible production methods.
Waste minimization remains a primary goal. We reorganized our process water reclaim systems after noticing loss rates exceeding targets. Today, process water undergoes on-site treatment, removing benzene traces before recycling or safe disposal. Occasionally, end-users inquire about the lifecycle data for mono with benzene; we share our internal audits and third-party assessments to back up claims of reduced carbon footprint per ton shipped, supporting our customers’ sustainability goals.
Comparing mono with benzene to related aromatic intermediates, some users point out easier handling—especially where alternative materials require stabilizers or extra drying steps. We engineered our product for broad compatibility and tailored volatility, balancing the drive for conversion rates with safety margins valued in industrial-scale production. Other suppliers sometimes offer blended or downgraded fractions for cost savings, yet at the expense of reproducibility and downstream performance. From a manufacturer’s perspective, experience has shown these shortcuts sometimes result in double costs due to line flushing, lost yields, or unexpected re-blends.
Technicians see the direct result of reliable quality through fewer batch-to-batch investigations and less equipment fouling. This difference shows up throughout operations, from catalyst longevity to smoother packaging lines for customers formulating finished goods. Our ongoing investment in raw material qualification and in-line process controls means end-users can plan purchasing and production schedules without worrying about sudden changes in product quality.
In epoxy resin manufacturing, project teams relay that switching to our grade helped resolve inconsistent cure times and improved clarity—a result attributed by chemists to the consistent elimination of interfering impurities. Operational feedback drives our ongoing adjustments; even small changes, like updating line cleaning protocols between runs, can magnify results for customers managing dozens of intermediates in their supply chain.
Pharmaceutical partners using mono with benzene in synthesizing API intermediates report improved crystallization profiles and lower downstream purification loads. By maintaining strict adherence to process documentation and encouraging open lines of communication with their QC teams, we saw a measurable drop in non-conforming lot returns over a two-year period.
Electronics manufacturers with stringent demands on residue content and olfactory neutrality benefit from our investment in contaminant reduction. Device yields depend on reliable input materials, and several process engineers have confirmed better process uptime and reduced cleaning cycle times in post-installation audits.
Through our years of collaboration with plant operators, research chemists, and technical buyers, recurring process bottlenecks can often be traced to overlooked impurities or unanticipated interactions with production equipment. By providing detailed analysis with every order—including impurity fingerprints and historical batch data—our users adjust recipes and calibrations with reduced trial-and-error overhead. Where legacy infrastructure sometimes clashes with new feedstocks, our technical service teams organize site visits and online troubleshooting, offering not just advice but concrete parameter recommendations based on similar customer experiences.
Waste stream management offers another opportunity for shared learning. Facilities lacking on-site remediation find value in our adapted return and disposal program, closing the loop in a way that aligns with both safety obligations and emerging regulatory expectations. By setting up recurring review meetings with customer EHS managers, issues stay small and solutions surface before compliance deadlines.
From process integration to supply assurance, the pathway is built on openness to change and willingness to reinvest in best practice—lessons learned from years of real-world production, not just textbook theory.
Mono With Benzene continues to form the backbone of industrial synthesis for intermediates that power daily life, from materials science to medical applications. In keeping pace with evolving demands across these sectors, we remain committed to rigorous, transparent production and a responsive, partnership-driven support model. Each improvement cycle—on the production line or in the field—feeds back, sharpening the reliability and relevance of our offering. Because, in our experience, what matters most is not only what happens in the lab or at the depot, but what end-users accomplish with the product at scale in ever-evolving industries.
