| Names | |
|---|---|
| Preferred IUPAC name | N,N'-didodecylethane-1,2-diamide |
| Other names | Bis(N-dodecyl)ethylenediamide Ethylene-bis(N-dodecanamide) Ethylenebis(N-lauroylamide) Ethylenebislauramide EBLA |
| Pronunciation | /ˈɛθ.ɪˌliːn bɪz lɔːˈræm.aɪd/ |
| Identifiers | |
| CAS Number | 110-31-6 |
| Beilstein Reference | 1445088 |
| ChEBI | CHEBI:53421 |
| ChEMBL | CHEMBL4297655 |
| ChemSpider | 87299 |
| DrugBank | DB14074 |
| ECHA InfoCard | 03b807c9-ecb1-48d4-99f4-be7b8b19440c |
| EC Number | 245-442-7 |
| Gmelin Reference | 111800 |
| KEGG | C19236 |
| MeSH | D004991 |
| PubChem CID | 30347 |
| RTECS number | KK4900000 |
| UNII | A27G7R16U9 |
| UN number | UN3077 |
| Properties | |
| Chemical formula | C26H52N2O2 |
| Molar mass | 621.09 g/mol |
| Appearance | White powder |
| Odor | Odorless |
| Density | 0.97 g/cm³ |
| Solubility in water | Insoluble in water |
| log P | 3.82 |
| Vapor pressure | Negligible |
| Acidity (pKa) | >14 (estimated) |
| Basicity (pKb) | pKb ≈ 3.5 |
| Magnetic susceptibility (χ) | -7.92e-6 cm³/mol |
| Refractive index (nD) | 1.325 |
| Viscosity | Viscosity: 20-40 mPa·s |
| Dipole moment | 3.73 D |
| Thermochemistry | |
| Std molar entropy (S⦵298) | 887 J·mol⁻¹·K⁻¹ |
| Hazards | |
| Main hazards | May cause respiratory irritation. Causes serious eye irritation. Causes skin irritation. |
| GHS labelling | GHS07, GHS08 |
| Pictograms | GHS07,GHS09 |
| Signal word | Warning |
| Hazard statements | Harmful if swallowed. Causes skin irritation. Causes serious eye irritation. |
| Precautionary statements | Precautionary statements: P261, P273, P280, P305+P351+P338, P337+P313 |
| Flash point | 240°C |
| Autoignition temperature | > 343°C |
| Lethal dose or concentration | LD50 (oral, rat): >5000 mg/kg |
| LD50 (median dose) | LD50 (median dose): > 2,000 mg/kg (rat, oral) |
| NIOSH | K0789 |
| PEL (Permissible) | PEL (Permissible Exposure Limit) for Ethylene Bis Lauramide: Not established |
| REL (Recommended) | 10 mg/m³ |
| Related compounds | |
| Related compounds | Ethylene bis(stearamide) Octadecanamide Lauramide Ethylenediamine Stearic acid |
| Aspect | Details |
|---|---|
| Product Name & IUPAC Name |
Product Name: Ethylene Bis Lauramide IUPAC Name: N,N'-ethane-1,2-diylbis(dodecanamide) |
| Chemical Formula | C26H52N2O2 |
| Synonyms & Trade Names | Ethylene Bis(dodecanamide), EBL, EBO, EBLamide, Bis(N-lauroyl)ethylenediamine. Trade names, if used, are defined per customer negotiation or local market conventions and vary by producer or downstream modifier. |
| HS Code & Customs Classification | For international trade and customs purposes, most batches are classified under HS Code 2924.29 for amidic organic derivatives containing oxygen. Final HS position may vary based on region-specific classification policy, product grade, intended application, or customer customs guidance. |
In chemical manufacturing, Ethylene Bis Lauramide typically arises through a condensation reaction between lauric acid (dodecanoic acid) and ethylenediamine. The route and sequence influence side product formation, especially alkyl amide homolog designates and incomplete amidation residues. Production grade depends significantly on chosen raw material quality—feedstock purity and fatty acid origin alter both impurity background and color tendency.
The manufacturing department pays close attention to moisture levels. High water presence during condensation fosters incomplete conversion and impacts pellet integrity downstream. Batch variability in purity and physical properties often relate to differences in reactant sources and process temperature control. Key control points include acid-to-amine molar ratios, catalyst choice (if used), agitation setup, and vacuum application.
Volatile matter, unreacted amine, remaining acid content, and specific color shades vary by production run and grade. Applications in plastics incorporate both technical and food-contact grades, although regulatory compliance hurdles and analytical release requirements diverge sharply at this interface. Commercial grades split further for melt point, particle profile, and free acid/amine contents, all sensitive to process route and purification extent.
Practical handling and storage require consideration of melting point spread, end use filtration specifications, and downstream blending. Low-melting out-phases yield handling complications in heated transfer or during compounding, motivating tight melting point control for premium grades. Residual fatty acid content matters for downstream polymer processing—excess free acid creates compatibilization problems in polyolefin masterbatch applications.
Unique identifiers—product code, lot trace, IUPAC, formula, and HS code—link directly to inventory control and export documentation. Quality control finds value in simultaneous cross-referencing of these identifiers to lot-specific analytical reports and MSDS documentation. Divergence in HS code assignment surfaces at customs depending on declared end use or blending with other waxes and lubricants, so technical staff must often clarify application intent with buyers to pre-empt import/export issues.
Our technical support often assists with harmonized documentation for both importing customers and end users. Classification can also shift based on in-house modifications, finished blend form, and even customer-relabeling needs, which highlights the importance of precise, up-to-date recordkeeping from raw material intake to batch shipment.
Production output yields ethylene bis lauramide as a waxy solid, typically observed in flake or powder form at room temperature. Color can range from white to off-white depending on both raw material quality and post-synthesis purification. Odor tends to be faint, sometimes slightly fatty due to residual lauric acid, but low odor is a benchmark for higher purity grades.
Melting point varies by grade and minor impurity content, generally falling in a well-fitting range for amide waxes. Boiling point is less useful operationally, as ethylene bis lauramide tends to decompose before boiling under normal atmospheric pressure. Density shifts with cooling rate during solidification but often centers on typical synthetic amides. For storage and downstream dosing, melting behavior remains the most operationally significant property.
Routine quality checks confirm stability under factory, transport, and downstream compounding conditions. Direct sunlight, strong oxidizers, or high-temperature exposure may cause yellowing or amide bond cleavage. Finished product is sensitive to acidic and basic hydrolysis at elevated temperatures—processing guidelines stress neutral pH handling during solution making.
Ethylene bis lauramide demonstrates low water solubility; typical use requires dispersion or dissolution in hot organic solvents or plasticizer systems. Tech support often recommends pre-melting or solvent-mixing above the melting point to ensure uniform distribution. Full compatibility with target matrices should be established by pilot-scale dissolution and performance testing.
Dialed-in specification tables reflect target sectors, from plastic masterbatches to lubricants. Specifications typically call out physical form, color (expressed as APHA or Gardner), amide purity, acid value, and moisture content. Tight color and purity control carries extra weight for compounding and food contact applications.
Dominant impurities include unreacted lauric acid, monoamide fraction, and traces of ethylene diamine derivatives. Manufacturing process determines both impurity spectrum and achievable limits. Finished product lots are certified only after impurity inspection passes both internal and (where required) external regulatory limits.
Physical and chemical properties follow in-house standard operating procedures traceable to accepted industry norms. Typical methods include melting point via capillary or DSC, color via colorimetry, HPLC or GC for purity, and Karl Fischer for moisture. Customers with custom requirements may designate alternate or additional methods.
Lauric acid and ethylene diamine quality drive process performance. Suppliers for lauric acid are selected for consistent fatty acid distribution and low color. Ethylene diamine undergoes additional QC on arrival to confirm amine value and moisture profile, reducing risk of side reactions and process drift.
Industrial synthesis involves direct condensation between lauric acid and ethylene diamine under controlled heat and vacuum. Catalyst selection, charging sequence, and agitation profile are tuned for scale and application specificity. The reaction liberates water, which is continuously removed to drive amide formation to completion.
Key control points include acid-amine ratio, temperature profile, and water removal rate. Formation of monoamide and unreacted acid are minimized through precise temperature and stoichiometry control. Post-reactor, finished mass typically passes through vacuum distillation and filtration. Batch color, residual acid, and off-odor serve as pass/fail for lot release.
QA teams enforce zero-tolerance thresholds for critical product attributes based on customer specifications. Each lot receives full traceability from raw material batches through reactor logs and in-process testing. Final batch release occurs only after passing all specification checkpoints, including impurity screening and function tests appropriate to the grade.
End users may encounter hydrolysis under highly acidic, basic, or oxidative conditions, splitting the bisamide into corresponding acid and amine fragments. No catalytic decomposition is observed under neutral, dry, or standard compounding environments.
Most chemical modification work focuses on surface activation or derivatization to functionalize the amide group for specialty applications. Standard industrial practice uses non-catalyzed processes at elevated temperatures, under inert gas when purity is critical. Purposive blending with stabilizers or color inhibitors occurs prior to downstream processing if required.
Ethylene bis lauramide serves as a precursor or co-component in polymer lubricants, slip agents, coating additives, and specialty lubricant blends. Downstream modifications are shaped by matrix compatibility and specific functional requirements rather than universal chemical reactivity.
Stable bulk storage maintains product flowability and color stability under cool, dry, and clean conditions. Humidity control avoids agglomeration. Direct sunlight or UV accelerates color and property drift, so low-light warehousing is standard. Nitrogen blanketing may be specified for high-purity grades.
Common packaging materials include HDPE drums, lined fiber drums, or polyethylene bags. Compatibility with product depends on both storage duration and exposure to high ambient temperatures. Metal containers without suitable inert lining can cause product yellowing and contamination from ions.
Shelf life depends on grade, packaging, and storage practice. Typical signs of degradation include discoloration, formation of lumps, or shift in melting point. Customer-specific handling and shelf life guidance is provided based on delivered grade and region.
Current GHS classification reflects available toxicology data and product impurity profile. Standard industrial practice includes review of updated literature and periodic re-assessment based on new research or regulatory guideline changes.
Manufacturing teams maintain updated hazard statements based on raw material and final product risk. General advice includes avoiding dust generation, use of local exhaust during bulk handling, and maintaining basic hygiene protocols in case of prolonged exposure. Detailed handling guidelines are grade- and use-specific.
With low acute oral and dermal toxicity observed in animal models, routine handling does not create significant workplace risk under established protocols. Residual reactants and minor byproducts may alter workplace exposure risks, highlighting the importance of rigorous batch QC from both a regulatory and occupational health standpoint.
No established regulatory exposure limit applies in all jurisdictions, so manufacturing safety protocols draw on internal risk assessments and sector best practices. Engineering controls, PPE, and spill response standards are matched to batch size, packaging form, and application sector. Plant-specific standards respond to evolving regulatory and client safety documentation demands.
Production runs for Ethylene Bis Lauramide always tie back to feedstock availability and the operational status of our key reactors. Output per campaign depends on the product grade—technical, industrial, or high-purity versions use distinctly designed campaign setups and may run with different throughput limitations due to purification steps and contamination controls. Existing reactor train capacity allows scale-up, but flexibility remains governed by upstream raw material sourcing, especially for ethylene diamine and lauric acid derivatives. Short runs for samples or high-purity batches often extend plant turnaround. Predictable volume orders—those matched to ongoing customers—receive allocation priority, making availability more reliable for repeat buyers.
Typical lead times reflect current warehouse position and the required product grade. Urgent supply for standard technical grades is possible from existing stock if prior arrangements cover specification alignment. High-purity or customized packaging formats extend lead time due to off-line processing and batch-specific testing. For new customers, final MOQ depends on supply chain stability, warehouse cycle, and grade mix. Large-volume customers may negotiate rolling purchase orders to lock in supply schedules, while spot buyers accept lead time variability tied to plant loading.
The packaging approach responds to moisture sensitivity and customer handling process. Regular grades commonly ship in 25 kg PE-lined kraft bags or 500/1000 kg FIBC. High-purity or special certification batches use double-sealed drums with inert barriers or foil liners upon request. Packaging selection involves a clear trade-off between material barriers, downstream ease of handling, and compliance with customer audit protocols.
Shipping schedules correlate to lot release and transport availability. Sea freight aligns with port proximity and international routing, while inland delivery respects restrictions for chemical cargo. Payment terms depend on customer standing and credit history. New buyers may use prepayment or confirmed L/C; established partners can negotiate extended or milestone-based settlements if annual volume projections support such structures.
Raw material cost directly reflects global trends in lauric acid derivatives and ethylene diamine pricing. Both feedstocks show volatility linked to petroleum price swings and supply chain disruptions, with lauric acid especially sensitive to tropical oil crop yields and logistically complex routes. Energy consumption in hydrogenation and distillation units also contributes significantly, especially in high-purity product streams.
Not all grades of Ethylene Bis Lauramide command the same price. Technical grades, produced in large campaigns with wider impurity windows, maintain entry-level price points. Higher purity or regulated grades (such as those destined for food contact or high-performance plastics) involve more expensive precursor streams and downstream purification, reflected as price steps. Batch certification for ISO, REACH, or other regulatory schemes involves process documentation, raising release costs. Bulk packaging reduces per-unit expense, while small or specialty containers cost more per kilogram due to handling and material choice.
Capacity additions over the last three years, especially in Asia, have altered the supply landscape. Demand continues rising for polymer processing and specialty lubricant segments, with regional spikes driven by local plasticizer and dispersant plants. Timing of capacity ramp-ups or plant outages affects short-term pricing, but structural demand holds steady.
United States and European producers focus on high-certification and value-add niches. Japan keeps a stable but limited local supply, mainly for integrated specialty downstream use. India’s output growth serves both domestic and regional Asia markets but faces variable logistics. China currently leverages large-scale production advantages and flexible downstream distribution, but regulatory tightening could limit new capacity buildup.
By 2026, expect cautious price firmness for specialty and certified grades as regulatory and compliance forces increase cost base. Technical grades face price pressure from rising Asian production, barring raw material cost spikes. Macro factors—feedstock volatility, regional protectionism, currency shifts—may all impact realized transaction prices. Industrial users with stable contracts gain insulation, but spot buyers remain exposed to rapid short-term swings.
Price and supply forecasts integrate internal capacity planning, upstream feedstock contract observations, and regional trade flow statistics collected from chemical industry journals, customs data, and customer request patterns.
Some Asian plants have announced upgrades aimed at higher purity production, responding to downstream regulatory tightening. Certain Western regions report shortages linked to scheduled plant maintenance or shipping disruptions from weather events.
Shifts in food contact and plastics additive regulations, especially under EU REACH and related bodies, now demand batch-specific documentation and validated impurity profiles. Continuous review of compliance standards dictates in-plant testing and certificate documentation, especially for export.
Forward planning includes diversified sourcing of both lauric acid and amine streams, contingency packaging inventory, and active monitoring of regulatory notices. Engagement with customers on advanced forecasting and grade-specific requirement communication reduces allocation risk and supports compliance-driven release management.
Ethylene Bis Lauramide serves as a specialty slip agent, anti-blocking additive, and surface modifier across a set of demanding fields. Typical sectors absorbing our EBL grades include:
| Application | Matching EBL Grade | Key Grade Characteristics |
|---|---|---|
| Film & Sheet Production | High-purity, low-ash masterbatch grade | Low volatile matter, strict control of particle size for dispersibility |
| Cosmetic & Skin Contact | USP/NF or regionally certified cosmetic grade | Stringent color, odor checks; bioburden management |
| Rubber Process Lubricant | Standard industrial grade | Broader tolerance on minor byproducts, optimized for cost-in-use |
| Printing Ink Modifiers | Mid-purity, low-residue grade | Controlled filtration, color stability emphasis |
| Textile Fiber Auxiliaries | Custom viscosity, tailored bulk density | Batch-to-batch rheology checks, limited surfactant residue |
The parameters most scrutinized shift according to end use. In film production, consistent melt point and purity drive downstream performance. Printing ink makers will focus on color stability, odor, and residual amide levels since downstream process temperatures reveal off-spec fractions. In personal care, trace contamination and hydrolytic stability tip approval. For rubber, particle flow and blend consistency take precedence over ultra-low residuals.
Start by clarifying the operational conditions and functional targets — film slip improvement, mold release, pigment dispersant, or another. The critical use determines which impurities or fractions require restriction and which performance check is weighted during QC.
Plastics meant for food contact, medical, or personal care push selection toward grades supported by food contact notifications, monograph compliance, or bioburden certification. In our systems, only grades specifically produced and isolated on dedicated lines qualify for these requirements. Standard industrial EBL may not meet region-specific regulations.
Purity dictates off-smell, migration, and reaction compatibility. Higher purity restricts carryover of C18/C16 co-amides and colored side-products typically found from raw acid variation or incomplete reactions. Technical support can compare purity and color ratings from latest quality records.
Annual demand determines whether we supply from campaign-based, large-lot runs or weekly small-batch units. For heavy formulation consumption, the most cost-effective grade balances acceptable impurity profile and handling properties with raw ingredient sourcing constraints. Lower volumes may allow more customized specification if batch scheduling permits.
Before final acceptance, performance in your own production must be verified. We arrange advance samples, accompanied by full batch QC documentation. Customer trials confirm suitability regarding processing, filtration, and final product property — especially in applications sensitive to melt flow, volatilization, or residue.
Raw material selection remains the first determinant of finished EBL properties. Any deviation in lauric acid quality or ethylene diamine purity introduces shifts in byproduct spectrum, so lot-specific traceability and incoming test protocols are mandatory. Synthesis routes leveraging high-temperature condensation under inert gas allow faster conversion but require intensive volatile control and focused distillation. Lower temperature methods trade throughput for color preservation.
Key control points during EBL production: reaction completion, residual free acid, and amine monitoring at defined checkpoints, guided by in-line spectroscopy where installed. Batch consistency is managed by strict filtering and screening, with statistical controls on melt point and color value. Impurities generally arise from off-spec reactants or uncontrolled temperature gradients; we mitigate with tight thermal profiles and immediate lot segregation on deviation.
Each outgoing grade must clear batch records, specific QC tests, and, for sensitive applications, additional external validation. Final release criteria are recorded in our quality system and customer-agreed specification log.
Our production sites maintain a documented quality management system aligned with internationally recognized standards. Routine internal audits and certification processes help ensure continuous improvement and management accountability at every stage from raw material sourcing to product shipment. Regulatory and customer audits focus on batch traceability, manufacturing records, and preventive control systems implemented in line with prevailing chemical industry norms. Certification status, audit outcomes, and related evidence are updated in our supplier dossier for inspection by qualified buyers on request.
Third-party verification of product-related compliance depends on application and regional market requirements. For industrial lubricants, plastics, or coatings, registered customers may request certification documentation such as food contact statements, REACH compliance declarations, or regionally mandated certifications. Detailed testing, such as analysis for specific regulatory-restricted impurities, follows protocols defined by customer or legislative standards, which vary per end-use. Delivery lots are typically paired with certificates of analysis referencing the actual analytical batch data.
Every batch of ethylene bis lauramide leaves the facility with a controlled release record. Certificates of analysis include test result sheets for appearance, melting point range, acid value, amine value, and, where applicable, moisture level. Custom documentation—such as vendor-specific regulatory questionnaires, analytical method validation data, or long-term stability documentation—is issued per request and project scope. Supporting reports detail the analytical methodology and internal standard references used. Detailed specifications can be defined according to the product grade and region of application, especially if non-standard purity levels or performance characteristics are required in downstream use.
Core production output for ethylene bis lauramide is planned based on both rolling forecast demand and firm customer commitments. Production schedules prioritize high-frequency buyers and those operating under annual contracts. For long-term cooperation, production lines dedicated to particular grades can be arranged with mutually agreed exclusivity. Customers with seasonal or irregular ordering cycles may join a rolling procurement and release scheme, allowing for guaranteed reservation of capacity with flexible call-off terms. Such arrangements help balance lead time, stockholding, and logistic needs between partners.
The operational plant configuration draws on feedstock from vetted raw material suppliers, with procurement policies reinforcing continuity and risk management. Line capacity and headspace accommodate both forecasted volume and schedule deviation caused by maintenance, regulatory inspections, or force majeure events. Batch-to-batch consistency is maintained by tracking process control parameters and enforcing final release criteria based on grade- and customer-specific standards. This approach helps avoid off-specification shipment, especially for sensitive downstream formulations.
Sample quantities and grades are available for benchmark evaluation or formulation testing. Requests undergo technical and compliance review to confirm intended use and grade compatibility. Samples, when approved, are dispatched alongside a full analytical profile and safety documentation. For applications dependent on specific purity or performance, technical teams engage with the recipient to clarify tolerance ranges and test methods to ensure valid product evaluation.
Business cooperation modes adapt to customer procurement models—spot purchasing, long-term contract, blanket call-off, or project-based supply can be negotiated according to the customer's forecast, formulation window, and inventory practices. Logistic terms, packaging configuration, and documentation flow are all specified ahead of the first commercial shipment. For critical demand profiles, emergency supply protocols and safety stock management arrangements are part of the project planning phase. Commercial flexibility is balanced by shared visibility on market trends, feedstock price volatility, and regulatory changes impacting raw material flows or logistics.
Within our production and technical teams, most recent R&D resources target melt point stability and dispersibility improvement, both of which directly impact downstream incorporation in plastics processing and hot-melt adhesive manufacturing. Projects focus on controlling by-product content and enhancing compatibility with engineering thermoplastics. These areas are driven by customer demand from film extrusion and masterbatch compounding sectors, where end-use consistency depends on both chemical purity and functional performance in complex matrix systems.
Ethylene Bis Lauramide traditionally supports processing as a slip and anti-block agent in polyolefin and PVC films. We now record growing interest from high-end coatings, specialty ink formulations, and nonwovens, where chemical inertness, waxy lubricity, and controlled migration can extend equipment run life and enable new rheological profiles. Early-stage development in biodegradable polymer systems seeks to harness the unique rheology without compromising compostability targets. Formulation teams prefer grades with controlled particle size and reduced residual fatty amide impurities for sensitive, specification-driven markets.
Process engineers deal with batch-dependent color stability and haze, often linked to raw lauric acid variability and catalyst residues. Managing low-level amine formation and achieving narrow melting range means continuous attention to reaction parameters and purification stages. Consistency improves with closed-system esterification and rigid feedstock pre-treatment protocols; recent pilot runs show reduced lot-to-lot haze and color drift, critical for transparent film applications.
Ethylene Bis Lauramide demand tracks closely with infrastructure upgrades and packaging modernization in Asia-Pacific and Europe. Film and fiber applications are expected to show moderate volume increase as regulations tighten on alternative waxes and slip agents. Compounders seek reliable, stable supplies and emphasize post-consumer recyclability, pushing for higher traceability and detailed impurity mapping at the supplier level.
Manufacturing departments see the need to adopt continuous processing to bolster batch uniformity and cut energy intensity. Inline monitoring tools, such as near-infrared and particle-size imaging, accelerate troubleshooting and quality release. Future technology upgrades prioritize feed purity, modular process trains for rapid grade changeover, and solvent-free routes to minimize environmental load and simplify waste management. Close collaboration with polymer producers on surface migration and extractables will drive specification alignment and process adjustments.
Raw material selection moves toward traceable, renewable-source lauric acid. Sourcing teams evaluate coconut and palm oil derivatives from certified supply chains. Waste minimization anchors process design, with increased solvent recovery and integrative energy reuse sections in new plant layouts. Product innovation efforts aim to develop grades with verifiable low-impact lifecycle, supporting both performance targets and end-user sustainability reporting. Where customer requests dictate, dedicated low-residual-amide versions are offered to reduce downstream rework in sensitive electronic or optical packaging.
Our application specialists remain available throughout evaluation, scale-up, and routine production. Most incoming consultations address formulation adjustments, migration rate optimization, and trouble-shooting of handling or dosing equipment. Direct plant visits and digital technical workshops enable problem-solving rooted in real-world customer processes.
Technical service supports lab and full-scale plant trials, especially for customers converting to specialty grades or shifting to new regulatory frameworks. Detailed batch data, impurity profiles, and melt behavior trends can be provided on request to facilitate rapid qualification within highly regulated or high-purity application spaces.
Quality assurance extends beyond shipment, including traceability documentation for each lot. Our release criteria depend on grade, application targets, and mutually defined customer QC checkpoints. Feedback channels speed up responses to performance deviation or appearance issues observed in the field, and regular supplier audits ensure process and supply consistency. Logistics teams track delivery histories and manage inventory rotation to minimize shelf-life concerns, especially for high-purity or specialty application contracts.
In our own facility, we handle the full synthesis and finishing of ethylene bis lauramide, starting from verified raw materials through controlled process steps. Our site manages all process parameters, which means accurate melting point, particle properties, and appearance align with industrial expectations each batch. Every shipment stems from the same core production lines, not mixed from outside suppliers.
Ethylene bis lauramide addresses the requirements of many manufacturing sectors. In plastics processing, customers use the material as an internal and external lubricant to control flow properties in extrusion and molding of polyolefins, PVC, and engineering resins. Especially in masterbatch and color compound production, our grade modifies surface finish and processability. Rubber and tire formulators incorporate ethylene bis lauramide as a mold release aid and flow enhancer. Powder metallurgy, ink, and coatings plants benefit from its anti-blocking and surface slip qualities in their own processing environments.
We operate under a strict batch tracking system paired with continuous QC checks, supported by routine melt point, purity, and residual analysis. No material leaves the plant before meeting predefined control ranges. Sampling retains and automated paperwork follow each lot, supporting full traceability into end-customer processes. Customers use the same reference specifications and technical documentation issued with every production lot.
Our plant fills ethylene bis lauramide in a range of bulk and secondary packaging options. Standard forms include 25 kg bags and 500 kg super sacks designed for automated handling in industrial settings. Each packaging method prioritizes protection from moisture, caking, and product loss during storage and transport. Routings and shipment schedules rely on our internal logistics team, not secondary shippers or external consolidators. Our track record for on-time supply supports long production campaigns at customer sites.
Our technical team, based alongside the manufacturing floor, provides direct application support for process engineers and quality managers. We document historical performance in key formulations and assist in troubleshooting process integration or output consistency. Most of our experience addresses continuous blending, high-shear compounding, and injection molding, including root-cause analysis for process interruptions.
We understand the downstream business impact for manufacturing clients, procurement teams, and distributors who manage ongoing supply agreements. Consistent product performance affects process efficiency, final part quality, and compliance with contract requirements. Our focus on stable production, tight batch controls, and reliable supply eliminates the uncertainty associated with fragmented sourcing or inconsistent quality. By working directly with our factory, partners benefit from predictable costs and process reliability at scale.
On our production lines, Ethylene Bis Lauramide—often abbreviated as EBL—shows up as a pale, slightly waxy solid with good thermal stability and low volatility. We consistently observe melting points in the range of 98–102°C, making it suitable for processing alongside a broad range of thermoplastics and thermosets. In its pure form, EBL resists water and most organic solvents at room temperature. Our chemists see firsthand the value in its high purity threshold and absence of odor, which means integration into sensitive formulations rarely introduces unwanted side effects.
The chemical backbone, built from lauric acid and ethylenediamine, gives EBL a balance of flexibility and slip. Whether we look at compounding or direct addition in downstream plastics, this backbone delivers consistent improvement in processing, particularly in drawing and extrusion. Lubrication is the standout property, which explains why we supply so much EBL for uses under high shear and elevated temperature, where tool wear and sticking can easily become expensive problems.
Customers often discuss compatibility issues with other lubricants, so we routinely test EBL with various polymers. In rigid and semi-rigid PVC, our experience demonstrates a substantial reduction in processing torque and improved plate-out performance. Polyolefins benefit too, mainly in the realm of mold release and surface smoothness. We supply both powder and micro-pellet grades, as some extrusion customers favor fine powder for faster blending while others focus on dust control.
From an engineer’s view, EBL pairs well with ABS, polystyrene, SAN, and other styrenics. The amide structure interacts favorably without causing resin brittleness or color shifts under most processing conditions. In polyethylene and polypropylene, our customers have less trouble with die build-up or film tearing when they use our product to fine-tune their line speeds and cooling cycles. We see broad demand in masterbatch production, where the thermal resistance and non-migrating properties of EBL help maintain consistency batch after batch.
While EBL joins easily with most common resins, we tell customers to monitor for over-lubrication. If levels climb too high, surface defects or optical haze may appear in transparent polymers. Our application chemists suggest starting with low doses and increasing only as needed, especially for films and thin-wall items. We send out detailed technical bulletins on the optimal dose range for specific resin types, as overuse wastes money without delivering added value.
Our technical team runs compatibility analytics with engineering plastics like polycarbonate or PA6. Here, EBL assists as a process aid but demands fine-tuning, particularly if downstream coating or printing follows molding. Our data supports its performance advantages, but direct contact with certain plasticizers or highly polar additives calls for review by process engineers.
We rely on high-efficiency reactors and rigorous process controls to limit batch variability. Routine checks for particle size, melting profile, and molecular purity underpin every shipment. We maintain documentation for traceability—so our customers know each bag aligns with industry standards for particle distribution and residual monomers. Packaging options include valved kraft bags, lined fiber drums, or custom tote configurations, supporting safe and clean handling on factory floors worldwide.
Direct dialogue between our teams and end-users often leads to new blends or improved formulations. Where friction, sticking, or tool corrosion emerge, we support with troubleshooting and optimization, guided by real-world manufacturing experience rather than just off-the-shelf formulas. For detailed product data or technical support, clients can reach our technical service center for consultation and guidance.
Every industrial customer who relies on Ethylene Bis Lauramide looks for more than just the base product—they need reliable delivery, predictable lead times, and a hassle-free purchasing process. For years, our team has managed high-volume, specialty, and custom packaging requests in sectors such as polymer compounding, inks, molding, and surface treatments. We craft every batch using quality-driven procedures and maintain transparency about what buyers can expect from us.
Manufacturing Ethylene Bis Lauramide at scale enables us to offer several packaging choices tailored for plant operations and downstream processes. Our most common packaging size is the 25 kg woven paper bag, with internal PE liners to protect product purity during international and domestic shipment. We also pack bulk orders in 500 kg or 1,000 kg palletized super sacks, meant for customers with automated dosing systems or those integrating directly from storage containers. Based on customer feedback and handling safety, we avoid small-volume retail formats; our packaging supports storage efficiency and safe material transfer during batch production.
We set our minimum order quantity for Ethylene Bis Lauramide at 500 kg per dispatch. This threshold aligns with our batch production scheduling and helps maintain material consistency across distributed lots. Customers working on R&D or sample-scale processing may request pilot batches, subject to manufacturing load and prior agreement. Our technical team provides batch references and retains retained samples for backward traceability, preserving transparency for all orders above the minimum dispatch.
Lead times reflect real factory schedules and raw material flow, so we publish realistic dispatch windows. Our standard lead time is 10-14 days from formal purchase order to ex-works shipment for standard packaging. During peak seasons, additional time may be added to the schedule, especially for orders above 10 metric tons or those requiring special palletizing, double-bagging, or extended documentation (such as halal, kosher, or non-standard REACH statements).
As the direct manufacturer, we prioritize keeping inventory above the reorder point to reduce customer disruption, but large back-to-back orders or major global logistics slowdowns sometimes influence planned shipment days. Our operations team updates order status regularly, and we invite customers to plan onboarding work in advance to ensure steady supply.
Over extended production runs, requests arise for custom packaging or alternate bagging materials (such as antistatic liners or export-grade shrink wrapping). Our facility supports these modifications—upstream communication with our technical staff helps streamline the process and avoids delays. Should a bottleneck occur with a global transport issue, we adjust ship dates quickly and communicate alternative fulfillment options directly, without third-party intervention.
We stand by our commitment to quality, consistent supply, and a direct path from our plant floor to your storage area. Our experience producing Ethylene Bis Lauramide at scale builds lasting partnerships with customers who value reliability over the long haul, not just on paper, but in actual shipment and day-to-day operations.
In international trade, proper classification of our ethylene bis lauramide is essential for smooth cross-border logistics and full regulatory compliance. The HS code for this compound typically falls under the category of industrial amides. We routinely declare exports under 2924.19, a heading that covers “acyclic amides and their derivatives; salts thereof.” Customs authorities in various jurisdictions reference the same foundational Harmonized System, which streamlines the process across most regions. It’s always worth noting that customs reclassifications emerge in some countries, so our shipping department tracks any local amendments to ensure accurate entries before shipment. For our clients, this approach minimizes inquiries from customs and expedites clearance, reducing demurrage and warehouse costs.
Packaging and documentation for chemical exports call for a methodical approach. A misclassified product or incomplete paperwork delays not only delivery but manufacturing schedules for our downstream users. We ensure that every international shipment includes a commercial invoice, packing list, and the certificate of analysis—prepared and verified by our technical team for each batch. If a specific destination requires a Certificate of Origin or a Free Sale Certificate, our logistics department arranges these through local chambers or relevant export authorities. Based on our regular supply to Europe and North America, we monitor customs updates so we can anticipate any changes or additional declarations required.
Most countries treat ethylene bis lauramide as a standard industrial additive, not subject to the same scrutiny as pharmaceuticals or regulated toxics. Our quality and regulatory compliance managers regularly review destination country lists for substances of special concern. We invest in ongoing staff training to recognize any indication that a pending shipment could be classified as hazardous or subject to special licensing.
Each consignment of ethylene bis lauramide is accompanied by a Safety Data Sheet prepared to the destination’s regulatory framework. For the EU, our SDS follows Regulation (EC) 1907/2006 (REACH), including all required hazard statements and workplace exposure guidelines. North American shipments adhere to GHS and comply with all relevant sections of OSHA’s Hazard Communication Standard.
Our test data and lot numbers are available for each pallet, ensuring traceability at the customs stage and for our users. When a customer’s audit team requests production batch documentation or a breakdown of raw material sources, we provide complete traceability reports within thirty-six hours. Importers in Asia or Latin America sometimes face process reviews on-site. Our technical support team cooperates directly with customs agents, chemists, and local plant inspectors to clarify any points related to nomenclature or handling.
Chemical import and export regimes can change quickly as regions update their environmental and safety frameworks. For instance, the HS codes may shift or secondary documentation becomes required after local revisions to trade agreements. Our sales and export documentation teams keep a steady eye on these developments by subscribing to government bulletins and consulting with trade authorities. These efforts enable us to ship ethylene bis lauramide efficiently and in full compliance, giving our customers confidence that delays and regulatory risks remain minimized at all stages of transport.
For product inquiries, sample requests, quotations or after-sales support, please feel free to contact me directly via sales3@ascent-chem.com, +8615365186327 or WhatsApp: +8615365186327
