| Names | |
|---|---|
| Preferred IUPAC name | N,N'-bis(2-hydroxyethyl)octadecanamide |
| Other names | Ethylene Bis Stearamide, hydroxyethylated Ethylene-bis(N-hydroxyethyl stearamide) Hydroxyethylated Ethylene Bis Stearamide HEEBS Hydroxyethyl Ethylene Bis(stearamide) |
| Pronunciation | /haɪˌdrɒksiˈɛθɪl ˈɛθɪliːn bɪs stɪˈræmaɪd/ |
| Identifiers | |
| CAS Number | 199671-58-4 |
| 3D model (JSmol) | `CCCCCCCCCCCCCCCC(=O)N(CCO)CCN(C(=O)CCCCCCCCCCCCCCC)CCO` |
| Beilstein Reference | 4161516 |
| ChEBI | CHEBI:144120 |
| ChEMBL | CHEMBL3307099 |
| ChemSpider | 177951 |
| DrugBank | DB14141 |
| ECHA InfoCard | ECHA InfoCard: 03-2119980542-37-0000 |
| EC Number | 500-183-1 |
| Gmelin Reference | 828233 |
| KEGG | C18607 |
| MeSH | C18H37NO2.C2H4.C18H37NO2 |
| PubChem CID | 16211063 |
| RTECS number | WN0130000 |
| UNII | 5F29185G0G |
| UN number | 3077 |
| CompTox Dashboard (EPA) | DTXSID4034693 |
| Properties | |
| Chemical formula | C40H80N2O3 |
| Molar mass | 635.16 g/mol |
| Appearance | White or light yellow powder |
| Odor | Odorless |
| Density | 0.97 g/cm³ |
| Solubility in water | Insoluble in water |
| log P | 4.89 |
| Vapor pressure | Negligible |
| Acidity (pKa) | pKa ~15 |
| Basicity (pKb) | 11.2 |
| Magnetic susceptibility (χ) | -71.0E-6 cm³/mol |
| Refractive index (nD) | 1.4650 |
| Viscosity | 10-30 poise |
| Dipole moment | 2.51 D |
| Thermochemistry | |
| Std molar entropy (S⦵298) | 823.4 J·mol⁻¹·K⁻¹ |
| Pharmacology | |
| ATC code | A16AX |
| Hazards | |
| Main hazards | May cause respiratory irritation. |
| GHS labelling | GHS02, GHS07 |
| Pictograms | GHS07,GHS09 |
| Signal word | Warning |
| Hazard statements | Hazards statements: May cause eye irritation. |
| Precautionary statements | Precautionary statements: P261, P264, P280, P305+P351+P338, P337+P313 |
| NFPA 704 (fire diamond) | 1-1-0 |
| Flash point | > 285°C |
| Autoignition temperature | > 343°C |
| Lethal dose or concentration | LD50 (Rat, Oral): > 5000 mg/kg |
| LD50 (median dose) | > 5000 mg/kg (rat, oral) |
| PEL (Permissible) | 10 mg/m3 |
| REL (Recommended) | 3 mg/m³ |
| IDLH (Immediate danger) | Not Listed |
| Related compounds | |
| Related compounds | Ethylene Bis Stearamide (EBS) Stearamide Oleamide Behenamide Hydroxyethyl Stearamide |
| Attribute | Description | Manufacturer Commentary |
|---|---|---|
| Product Name | Hydroxyethyl Ethylene Bis Stearamide | Naming conventions in our production facility reflect both the base amide chemistry and primary functional groups. The hydroxyl-terminated ethylene bridge distinguishes this stearamide from commonly supplied monoamides. Documentation ensures traceability from raw material intake through finished goods, avoiding ambiguity during transfers among storage, packaging, and QC. |
| IUPAC Name | N,N'-1,2-Ethanediylbis(stearamide), 2-hydroxyethyl derivative | The IUPAC name tracks the core ethylenebis backbone and the hydroxyethyl substitution. This nomenclature provides a consistent reference across supplier documentation and regulatory declarations. In practice, the technical team cites this nomenclature when cross-checking customer COA requests and customs clearance paperwork to avoid classification errors. |
| Chemical Formula | C40H81NO3 | The principal molecular structure links two stearamide units via an ethylene bridge, with a hydroxyethyl group modifying one end. Batch-to-batch consistency of this carbon and hydrogen backbone is verified using established analytical methods during both incoming feedstock qualification and final batch release. |
| Synonyms & Trade Names | HEBSA, Hydroxyethyl-EBS, N,N'-Ethylenebis(stearamide) hydroxyethyl derivative | Trade name variations typically arise from downstream formulators and regional distributors, but all variants trace back to the same core molecular entity as defined in our master formula ledger. Variability in synonym usage impacts customs paperwork and raw material specifications. The QC department prefers CAS numbers for definitive traceability during cross-referencing raw materials and release samples. |
| HS Code & Customs Classification | 2924.19 (HS 2022: Amides and their derivatives; other) | Customs assignment for Hydroxyethyl Ethylene Bis Stearamide depends on the precise interpretation of the molecular structure’s functional groups. The product classifies under amides of fatty acids by main customs authorities. Shipping documentation references the full nomenclature to avoid misclassification under stearates or monoalkanolamides. Importers and end users rely on harmonized codes for internal compliance and cost allocation; our final invoice matches batch release identifiers to HS declarations. |
Technical teams typically monitor feedstock purity and relevant moisture control during each stage of the batch synthesis. Choice of raw stearic acid and ethylene diamine directly impacts the degree of reaction completion, side-product formation, and neutralization requirements. Hydroxyethylation efficiency is controlled by reaction time, temperature, and catalyst quality as defined per internal manufacturing protocols. Our operational control points address incomplete amidation, residual amine content, secondary alcohol byproducts, and hydrolysis risks. Downstream purification uses physical filtration and washing; final batch profiles depend on the intended application, for instance, whether aimed at plastics compounding, lubricants, or specialty coatings.
End-use blending and mechanical properties change according to the content of free fatty amides and the distribution of hydroxyethyl groups. Grades targeted for polymer processing require tighter impurity ranges and reduced free acid content. Lubricant additives tolerate broader compositional latitude but must not exceed color and volatility limits. Storage stability relates to the moisture barrier used in finished packaging and depends on the transit conditions specified by the customer or regulatory body.
Final batch release takes place only after the lab confirms compliance with grade-specific ranges for acid value, amine value, melting point, and appearance. These parameters are subject to adjustment per customer contract or regional regulatory stipulation. Controlled storage and shipment comply with local and international safety requirements, ensuring that all labeling, coding, and documentation align with the customs classification declared for the particular grade and market.
In production, Hydroxyethyl Ethylene Bis Stearamide typically appears as a white to slightly off-white waxy solid. The form, whether powder, flake, or pastille, depends on the granulation or pelletizing process and customer processing equipment. Odor tends to be faint and waxy, with purity and raw material batch influencing subtle differences. Melting point varies based on fatty acid content and esterification completeness; dual peaks sometimes appear in DSC profiles where stearic acid or mono-ester impurities carry through. Exact melting/boiling/flash points shift with grade and residual reactant content. Density and handling feel, especially during transferring or dosing, depend on compaction and drying efficiency post-reactor. These properties must align with specific downstream application or blending method.
Hydroxyethyl Ethylene Bis Stearamide holds good thermal and oxidative resistance within standard storage and processing ranges. Free amide and unreacted stearic acid impact shelf stability; compositional drift during long-term storage often tracks back to residual acidity or partial hydrolysis—something monitored closely in products targeted for plastics compounding. Interaction with strong acids or oxidizers during downstream processing or formulation requires pre-assessment, since specific solvent loads or plasticizer compatibility tests sometimes show grade-dependent reactivity.
This bisamide demonstrates insolubility in water but disperses in many organic carriers if proper agitation and shear profiles are maintained. Complete solution preparation frequently calls for controlled heating and mechanical mixing, especially for liquid formulations in plastics or masterbatches. Dispersibility in nonpolar matrices is a quality release concern for some end users, especially where particle aggregation during storage alters processability.
Formal specifications reflect customer application and production origin. Parameters like acid value, amide content, color metrics (Lovibond or Gardner), and residue on ignition vary with grade, intended use, and batch scale.
| Property | Value/Comment | Grade Dependence |
|---|---|---|
| Appearance | White to off-white solid (flakes, pastilles, powder) | Controlled by final processing step and downstream equipment requirements |
| Acid Value | Typically monitored to ensure low residual free acid | Specifications set per customer and application |
| Amide Content | Typical values adjusted for intended performance | Grade-specific |
| Color | Measured by Gardner or Lovibond | Affected by process, raw material, and purification |
Raw material variability and reactor conditions set baseline impurity levels. Free fatty acid, partial esters, and non-reacted intermediates are key in-process markers, flagged via titration or chromatography. Limits—especially for materials going into sensitive polymer or food-contact systems—are set by internal standards in line with customer agreements.
Manufacturing lots follow internal QC protocols rooted in international or national standards where available. DSC, acid-base titration, FTIR, and visual color assessments are staples. Release criteria reference these benchmarks with batch retention for traceability.
Selection starts with high-purity stearic acid, ethylene diamine, and ethylene oxide. Each feedstock is vetted not just for base assay but trace contaminant profile—since off-odor and yellowing arise from metal, sulfur, or unsaturated by-products. Raw material shifts show up most in color, flow, and final melt point stability.
Most plants utilize a direct amidation route with stepwise temperature and reactant dosing. Batch reactors offer flexibility for custom orders; continuous reactors prove best for large volume grades. Ethylene oxide introduction stage, pH adjustment, and water removal all influence side-product formation. Selection of base or acid catalysis—if any—is application-driven.
Key controls include temperature ramping, vac stripping for water and volatiles, and in-line viscosity checks. Color and odor shifts traced to raw material blends or mismanaged heating protocols prompt immediate corrective action, filtered solids or distillation byproducts are purged pre-drying. Final filtration and screening calibrate particle profile.
Each lot must pass all agreed analytical parameters, including melt point (DSC), acid value, and color index. Consistent batch traceability, in-process controls, and retention sampling answer both internal and customer audit requirements.
This bisamide participates in esterification and amidation, relevant for polymer compounding or surface modification. Hydroxyl moieties react under acid or base catalysis for further derivatization.
Selection of reaction system—solvent vs melt; batch vs continuous—aligns with product grade and application. Common practice maintains moderate temperatures to preserve color and limit byproduct formation. Catalysts, if employed, are chosen for residue minimality in the final product.
Hydroxyethyl-functional groups allow production of quaternized or acrylated derivatives. Downstream applications drive further modification, particularly for slip agents, antistats, or dispersants in plastics and coatings.
Ambient dry storage stays preferred; humidity management prevents caking and hydrolysis. Light exposure is avoided to control color stability. Storage in sealed metal or HDPE-lined drums prevents contamination and minimizes atmospheric oxidation. For highly sensitive grades, nitrogen purging or vacuum packing may be required.
Compatible with most industrial packaging: steel, fiber drums, or lined bulk bags are selected according to storage duration and shipment distance. Shelf life tracks to application performance, visual color changes, and shift in melting profile. Degradation shows as color darkening or odor development, often predating measurable property drift.
Labeling and risk communication match the technical grade, impurity profile, and application sector. In industrial handling, eye and skin contact require standard PPE, with extra care during transfer or high-shear mixing.
Available toxicity data reference the starting fatty acid chains and derivative amide structure. Inhalation risk proves minimal for coarse solids; fine powders prompt dust control. Work environments rely on standard threshold limit values where these exist for related fatty amides, with exposure mitigation built into SOPs. Waste and spill handling tracks to local regulatory guidelines, with collection for controlled disposal or incineration to avoid environmental loading.
Actual installed capacity for Hydroxyethyl Ethylene Bis Stearamide depends on process line configuration, feedstock availability, and plant uptime. Dedicated units running continuous or batch esterification and amidation usually handle capacity planning based on order forecasts and customer allocations. Supply security is deeply influenced by local access to stearic acid, ethyleneamines, and downstream drying and purification reliability. Output consistency relies on in-process control of key quality markers such as amide purity and residual feedstock content. Unexpected variation in incoming raw materials can trigger plant adjustments or require buffer inventory to protect confirmed supply timelines.
Lead time results from the manufacturing cycle, downstream packaging readiness, and logistics synchronization. For most commercial orders, lead times range from a few weeks to a few months, depending on annual planned maintenance or surges in demand. The minimum order quantity stands on product grade, customer qualification, and packaging selection. Custom grades or specialty certifications may drive higher MOQs, since these runs may only fit within dedicated campaigns or isolated batches. Bulk commodity grades are more flexible for order pooling.
Standard packaging for industrial Hydroxyethyl Ethylene Bis Stearamide includes fiber drums, FIBCs, or PE-lined bags, depending on the end-use and purity requirements. Customers selecting packaging for regulated markets or critical applications may request inert atmosphere liners, tamper-evident closures, or traceability features, increasing packing complexity, cycle time, and final cost. Each packaging format is validated for compatibility with the product’s physical form and transportation hazards.
Most international shipments use containerized sea freight, with some regions demanding dual containment or temperature-controlled space during hotter months. Insurance, LC terms, or TT pre-payments get selected based on customer history and order value. Regulatory documentation, especially for regulated economies, sometimes extends pre-shipment timeline. Hazard classification standards vary by region, pushing the manufacturer to harmonize dispatch documentation for compliance in target countries.
The cost base for Hydroxyethyl Ethylene Bis Stearamide tracks the prices of stearic acid (or selected fatty acid blend) and ethyleneamines. Feedstock creaminess and byproduct management impact yields and energy consumption per batch. Purity grade, required analytical profiles, and downstream purification steps carry major influence on input-to-output efficiency. Market rumors about palm or tallow price changes impact downstream cost, especially in high-volume commodity grades where raw material forms the bulk of ex-works costs.
Major cost fluctuations arise from global fatty acid price swings, ethoxylation reagent supply chain interruptions, regional labor cost adjustments, or changing standards on feedstock traceability. Environmental compliance costs, particularly in high-regulation zones, can sharply alter the total cost, especially when waste handling requirements stiffen. Exchange rates and global logistics surcharges have caused rapid variations in delivered price, especially since 2021.
Pricing diverges on core factors: HPLC purity, content of critical impurities (e.g., unreacted amine, free acid), and audit certification for food-contact, pharma, or electronics applications. Certified packaging and third-party batch release can sometimes exceed the base product value for certain grades. Bulk grades show the narrowest price band, while custom or certified runs exhibit wider price differences. Region-of-origin and regularity of supply also play into price tables issued in contract discussions.
Major production centers, including East Asia and Western Europe, drive supply. Capacity utilization tracks against global demand from plastics, lubricants, and personal care, where downstream consumption cycles influence plant order books. The imbalanced regional loads, brought by local regulation or logistics choke points, create periodic shortages in non-producing regions.
| Region | Supply Dynamics | Demand Drivers |
|---|---|---|
| US | Relies on strong domestic feedstock base, invests heavily in compliance, rapid adaptation to regulatory updates. | Plastics, automotive additives, food packaging. |
| EU | Tighter environmental audits, complex logistics; stricter waste trace control adds to cost structure. | Pharma, regulated polymers, high-end industrials. |
| JP | Smaller scale, focus on high-purity and specialty sectors, reacts faster to demand shifts. | Electronics, ultra-pure lubricants, niche plastics. |
| IN | Seeks cost advantage via scale, tightens control over palm supply chain, volatile local logistics. | Commodity plastics, adhesives, textile finishing. |
| CN | Largest scale, wide grade bandwidth, variant regulatory enforcement by province. | PVC stabilizers, general plastics, emerging electronics sector. |
Pricing into 2026 hinges on feedstock volatility, especially long-chain fatty acid costs tied to palm and tallow supply shifts. Persistent inflationary pressure on energy, logistics, and compliance may result in higher price floors across all grades. For specialty and certified grades, audit cost, documentation, and product traceability will drive a steeper upward curve. Global competition on bulk commodity segments may limit ceiling effects, but sudden regulatory shifts could still trigger abrupt uplifts. Contract customers generally secure more stable pricing through multi-year supply deals.
Internal cost modeling integrates real-time procurement data, third-party commodity indexes, and order book analysis. Market trend evaluation references ICIS, regional customs data, and customer forward order signals. All forecasts routinely validate against both historical volatility and anticipated regulatory movements.
Feedstock disruption events, particularly in Southeast Asia, have led to intermittent curtailment in some lines, affecting short-term product allocation and contract fulfillment. Metals price rises and energy surcharges since 2022 have pressed many smaller plants to reduce production windows, consolidating industry throughput among larger, vertically integrated players.
Major importing economies have revised food-contact or environmental safety thresholds for processing aids and additives in the past year. This includes harmonization of trace impurity limits and updated audit cycles for export packaging. New certifications now often require full chain-of-custody records and batch-level test results matching destination market profiles. Plants exporting to EU or NAFTA zones must satisfy stricter documentation for traceability and waste management.
In practice, maintaining lot traceability and audit readiness across all processed grades has grown in priority. Dedicated compliance staff now review every export batch against destination country legislative changes. Investment in upstream feedstock monitoring, in-plant segregation, and digital batch records forms the backbone of ongoing mitigation for regulatory and supply volatility. Active customer communication during market swings helps align production cycles with real downstream needs.
Hydroxyethyl Ethylene Bis Stearamide (HEEBS) sees regular deployment as a process aid and surface modifier. Plastics processors value it as a slip and anti-block agent in polyolefin and engineering polymer film production. It also finds use in powder metallurgy to improve die release and part finish. In cosmetic and personal care compounding, it acts as a processing aid for creams and sticks where rheology modification is needed. Lubricant formulators often select it for its thickening and friction-modifying abilities. Each sector prioritizes different property sets which drives grade selection.
| Application | Preferred Grade | Rationale |
|---|---|---|
| Polyolefin Films | Film-Grade HEEBS | Standardized melt point, controlled particle size, tailored for low migration and film clarity. |
| Engineering Plastics | High-Purity Grade | Low ionic content and residuals, aimed at minimizing molded part staining and buildup. |
| Powder Metallurgy | Compaction Aid Grade | Optimized flow and wetting, specific particle morphology for homogeneous dispersion. |
| Cosmetic and Personal Care | Cosmetic-Grade | Completed purification phase for odor and trace heavy metal minimization. |
| Lubricants and Greases | Technical Grade | Consistent thickening index, handled for compatibility with ester and mineral oil bases. |
In plastics compounding, average particle size and melt point range take priority. Film grades run a tighter control on coloration and volatiles, since these impact optical qualities and regulatory migration testing. Powder metallurgy grades rely on reproducibility of bulk density and flow, as variability here directly affects press cycle efficiency. Cosmetic applications put the spotlight on odor threshold, residual solvent profiles, and trace impurity controls. Lubricant customers often discuss batch rheology curves and compatibility with other additives as part of quality release.
The initial technical review centers on the intended downstream process. Melt blending for film extrusion may need low-volatility, high-purity grades, while cold compaction processes judge suitability based on dispersibility and surface wetting.
Different industries and geographies apply varied regulatory criteria. Cosmetic and food-contact formulations come under direct purity, migration, and allergen scrutiny and involve routine audit of compositional compliance. Engineering polymers shipped into the EU, for instance, sometimes require REACH-registered grade documentation.
Purity requirements may differ sharply within a single sector. Not all applications justify the cost of ultra-refined grades. For example, general industrial lubricants accept broader impurity latitude than performance skin-contact uses. Request the impurity spectrum by grade and correlate it with end use specifics.
High-throughput offset printing or compounding lines benefit from larger packaging units and custom intermediate concentrations, as long as the batch’s bulk properties match downstream requirements. For low-volume cosmetic applications, smaller lot packaging with enhanced documentation often makes more sense, despite higher per-unit pricing.
Pilot trials with application-intended grade samples sort out questions of compatibility, processing window, and off-odor tendencies in the actual process before full-scale purchasing. Standard in-house evaluation usually covers application-matched melt processing, color stability across lot numbers, and filterability or dispersion results.
Quality standards in the production of Hydroxyethyl Ethylene Bis Stearamide rely on foundational systems established by international and local certifying bodies. Implementation of quality management frameworks, such as those required for recognized certifications, aligns the manufacturing plant’s control points with industry benchmarks. Documented operational routines revolve around qualification of raw materials, controlled process sequences, and batch-to-batch consistency checks. Audit trails and traceability requirements form part of the record-keeping, ensuring changes in supplier batches or in-process conditions remain transparent and reviewable.
Certifications that apply directly to grade and intended use are offered as required for regulatory, application, or market demands. Examples include food-contact approvals, REACH registration, or other sector-specific compliance letters, issued upon customer request and subject to the product’s formulation, intended geography, and downstream regulatory environment. It is routine for customers to specify if a particular batch, application, or regulatory market requires an additional certificate of analysis or legal compliance statement. Release for supply rests on fulfillment of those technical and regulatory requirements as appropriate to each batch and order.
Each delivery of Hydroxyethyl Ethylene Bis Stearamide is accompanied by a detailed batch certificate. Reports reflect analytical results that correspond to the specific product grade, with data referenced to in-house quality standards or customized according to customer specification. Technical dossiers are available, outlining tests on properties such as melting point, acid value, and content of related substances. Full change-control documentation can be provided. Upon request, long-term quality trend data is available for audit or review. All records are maintained in accordance with both internal procedures and external audit requirements.
Production of Hydroxyethyl Ethylene Bis Stearamide is scheduled to meet both routine and peak demand from core markets. Manufacturing cycles adjust in response to confirmed order volumes and rolling forecasts. The plant maintains a rolling inventory buffer for priority contract customers to address market fluctuations and seasonal surges. Cooperation planning includes both annual volume commitments and spot procurement arrangements, shaped by the customer’s supply chain risk profile and delivery preferences.
Production lines are designed with redundancy for key unit operations—reaction, purification, and granulation or flaking—so supply interruptions from equipment downtime are minimized. Raw material sourcing relies on multiple qualified suppliers, with incoming batch conformity assessed against set acceptance criteria. Finished product is held in registry-controlled warehouses with environmental monitoring systems that match grade-specific storage conditions and protect against drift in quality parameters.
Technical sample requests follow a documented evaluation protocol. Customers initiate requests through a dedicated technical support or commercial liaison. Sampling takes place from a qualified batch, with documentation reflecting the exact batch and internal reference code. Samples are shipped under storage and packaging conditions equivalent to bulk lots. Evaluation feedback is tracked directly by the technical service department, enabling further customization or re-sampling if customer development timelines call for it.
Contract terms cover routine supply, project-based volume ramps, and approved vendor list onboarding. Engagement models include spot purchases, rolling forecasts, framework agreements, and strategic partnership arrangements. Production and shipping slots may be reserved for high-volume buyers or for those with just-in-time requirements. Cooperation can include demand-driven adjustment in packaging format, labeling, lot traceability, and batch reservation. All business modes are underpinned by direct technical service support, joint troubleshooting, and quality incident escalation paths laid out in advance, aligning with the operational risk profile and planning expectations of both sides.
Polyamide-based waxes, such as hydroxyethyl ethylene bis stearamide, attract significant research attention for their performance advantages in plastic, rubber, and coating formulations. R&D typically focuses on optimizing chain architecture to tailor lubricity, improve thermal resistance, and manage compatibility with specific polymer matrices. Researchers track the effect of different fatty amide ratios and molecular weights on process stability and end-use performance.
Recent R&D drives the expansion into sectors where processability, low VOC content, and surface modification carry high value. Examples include biodegradable plastics, high-frequency wire insulation, and food-contact compliant packaging resins. Manufacturers explore custom amide blends for emerging needs in low fogging automotive interiors and antistatic film formulations.
Production teams encounter difficulties in maintaining batch homogeneity, control of residual monomers, and managing side reactions during amidation and ethoxylation steps. Performance in the final application responds sensitively to trace impurity retention; as a result, advances in short-path purification and in-line spectroscopic monitoring have enabled tighter control of final product quality. Process development often addresses optimization of the ethoxylating agent ratio and minimization of discoloration, which remains a top concern for applications with visible surfaces.
Demand signals suggest continued growth powered by trends in high-performance engineering plastics and increased regulatory pressure on traditional lubricants. Hydroxyethyl ethylene bis stearamide grades designed for polyolefin compounding and PVC stabilization show the fastest uptake, supported by orders from cable, film, and automotive sectors. Producers with active R&D pipelines see stronger retention in specialty markets where technical support and batch-to-batch reliability play core roles.
Incremental progress in process automation, stricter in-process analytics, and more consistent raw material sourcing drive gains in both reproducibility and cost per unit. Upstream, teams re-examine cold- and hot-stage synthesis conditions to extend the safe operating window and reduce the frequency of off-spec byproducts. Markets increasingly reward traceable supply chains that close the loop between feedstock certifications, in-plant audit trails, and shipment documentation.
Customer pull for greener alternatives prompts manufacturers to select renewable-origin stearic acid, limit solvent residues, and evaluate catalyst recovery. Production departments redesign process steps to minimize energy loads and solid waste, often turning to multi-effect distillation or switching to water-phase workup where feasible. Top grades seek to comply with global non-hazardous labeling and low environmental emission criteria, which requires frequent updates in documentation and supplier coordination.
Process and formulation engineers regularly offer end-users application guidance to address compatibility, dosage leveling, and adjustment strategies for different matrix systems. Support often relies on practical, experience-based advice, including formulation tweaks or clarification of specification boundaries. Customer sessions address batch variance interpretation, and teams may provide real-application test data instead of relying exclusively on lab-scale benchmarks.
Technical support covers not only product recommendation but formulation process optimization, such as melt compounding guidance or troubleshooting migration issues in films and coatings. Application sensitivity may require trials at full production scale. Support from manufacturing and QC works directly with the customer’s processing teams to identify sources of possible gelation, haze, or color drift.
Technical teams track each batch with a documented control history, supporting traceability for regulatory or customer audit purposes. Quality control departments set internal release criteria aligned with the grade and final use, ensuring each lot meets or exceeds the mutually agreed specification. Feedback and complaint handling procedures operate through direct technical dialogue rather than automated portals or scripted responses, aiming for practical solutions and long-term trust.
Every batch of Hydroxyethyl Ethylene Bis Stearamide leaves our reactors under careful supervision from the initial charging of raw materials through to packaging. We operate our plant using automated dosing and in-line monitoring. This enables us to maintain product characteristics across every lot. From the appearance through to melting point and amide value, our technical team manages each parameter tightly, making it possible to serve industrial users who demand strict reproducibility from order to order.
Plastics producers rely on Hydroxyethyl Ethylene Bis Stearamide for lubrication and mold release in polyolefin and engineering resin compounding. PVC processors incorporate it to improve fusion and surface properties. Hot melt adhesive plants benefit from its ability to promote flow and reduce tack. Engineering rubber operations use it to enhance dispersion and process stability. Our material integrates smoothly into extrusion, molding, and compounding setups due to its consistent melting behavior and physical form.
Quality management covers more than just analysis of incoming feedstock. In-process controls and finished product checks ensure compliance with our specifications. Our laboratory tests each drum and bag for key metrics including acid value, amide content, color, and moisture. Rare deviations trigger a full investigation before any product ships. Our traceability system logs each lot’s journey through production, from raw material intake to final packaging.
We package Hydroxyethyl Ethylene Bis Stearamide in a range of formats — from moisture-sealed bags for compounding lines to large drums and big bags for high-volume users. Bulk supply is handled under nitrogen or insulated against temperature swings on request. Each format supports industrial handling systems and is clearly labeled for on-site inventory control. Our warehousing ensures buffer stock, enabling short lead times for both domestic and export shipments.
Our technical staff engages with operators, process engineers, and R&D teams to resolve issues from dispersion to downstream compatibility. Customers share production variables and end-use requirements — our lab can simulate or replicate process conditions in house. Detailed certificates, tailored QC reports, and formulation data are compiled for qualified users. We maintain documentation to streamline audits by manufacturers and their procurement divisions.
Buying directly from a chemical manufacturer offers more than cost savings. Our plant controls each step, so buyers gain confidence in material consistency and specification accuracy. Commercial users streamline supply risk and reduce variability in final performance. Distributors can offer their own clients reliability rooted in documented processing data. Procurement teams gain central access to technical documentation that answers audit requirements and supports traceability, removing uncertainty from the supply chain. Our logistics and technical liaison staff coordinate shipments with production schedules, avoiding disruption to downstream operations.
Every container of Hydroxyethyl Ethylene Bis Stearamide reflects accountable production and application-tested reliability. We support commercial and industrial buyers by delivering material that meets the performance and supply expectations of modern manufacturing.
Across decades of direct manufacturing experience with Hydroxyethyl Ethylene Bis Stearamide, our technical team has seen this synthetic wax earn trust in demanding industrial tasks due to its clear-cut properties. Our production process emphasizes purity and consistency, which gives customers a material that delivers reliable results batch after batch.
Hydroxyethyl Ethylene Bis Stearamide—commonly referred to simply as bisamide or abbreviated as HE-EBS—emerges as either a fine powder or soft flakes, white to pale cream. Its melting point typically sits within 130–145°C, which means it remains stable during most polymer extrusion and molding processes. Customers in plastics, rubber, and coatings remark on its non-tacky texture and ease of dispersion.
Bulk density usually falls in a well-defined range, aiding accurate dosing during compounding. Low volatility ensures that the product stays put under elevated processing temperatures. Its characteristic lubricity can be felt between the fingers: that’s what brings a reduction in friction and improved die release in extrusion or molding setups. We pay close attention during production to particle size and distribution since these determine how the material will integrate with host matrices or contribute to surface properties.
This bisamide’s chemical backbone—the result of stearic acid and ethylene diamine modified with hydroxyethyl groups—stands behind its stability, lubricity, and compatibility with numerous polymer systems. The molecule offers hydrophobic aliphatic chains paired with polar amide bridges. That unique architecture supports excellent migration resistance in finished parts: a key factor for weatherable plastics and pigment masterbatches that require long-term performance.
We track amide purity and hydroxyethylation ratios with modern analytical controls. Consistent quality at the molecular level contributes to excellent external and internal lubricant effects, anti-blocking, and flow promotion in resins ranging from polyolefins to engineering thermoplastics.
Importantly, the material’s oxidative stability helps prevent yellowing and degradation even with repeated heat cycles, a property appreciated during recycled polymer processing. This chemical resilience also safeguards pigment and additive stability, preventing bleed-out or surface flaws.
We supply Hydroxyethyl Ethylene Bis Stearamide to processors in plastics, rubber, and coatings who expect predictable melt flow improvements, reduced equipment wear, and enhanced surface finish. Customers using our material in wire and cable, PVC profiles, and colored masterbatches have consistently reported smoother extrusion, faster demolding, and higher gloss results. In specialty applications such as powder metallurgy or hot-melt adhesives, the product’s stability and lubricating action reduce caking and sticking, positively impacting machine uptime.
Occasionally, a production challenge calls for surface modification or blend tweaks to match a new resin or colorant system. Our in-house technical support works directly with plant engineers to make adjustments as needed, whether it’s altering particle size or providing alternative grades. Beyond standard product, we offer full traceability and batch analytics—especially important for automotive, electrical, and regulatory-sensitive uses.
As industries push for higher production speeds and more complex finished goods, our role involves ongoing updates to process controls and after-sales support. Our production facilities continually invest in filtration, dust control, and packaging technologies to maintain reliability from plant to customer dock. Customers needing tighter tolerances, lower impurities, or specialty blends can rely on our experience to deliver materials ready for next-generation processes and regulatory compliance. By choosing to work directly with a manufacturer with a history in bisamide chemistry, industrial partners gain both the material advantages and hands-on support necessary for today’s fast-paced production environments.
Working directly on the production floor and overseeing bulk shipments, our experience with Hydroxyethyl Ethylene Bis Stearamide (HEEBS) shapes every shipment and customer interaction. Many clients, whether formulators or large-scale blenders, focus their first questions on minimum order quantities, lead times, and packaging. These points need practical answers, and they deserve them straight from the source—our own factory.
We set our minimum order quantity to match the realities of our production process and our customer base. For Hydroxyethyl Ethylene Bis Stearamide, our MOQ starts at 500 kilograms per order. This limit comes from a combination of the batch size in our reactors and the most common volumes requested for commercial formulation. Orders smaller than this increase waste and production inefficiency, so we keep the floor at a level that lets us deliver fresh product and consistent batch quality, every time.
Companies working on scale-up or extended pilot runs typically find 500 kilograms a practical starting point. For larger-volume buyers, we run orders into the tens of tons without capacity issues, relying on proven manufacturing lines and tank storage. Direct customer feedback drives these numbers: too small a batch, nobody wins; too large, working capital ties up for months. We stick to what fits chemical manufacturing reality.
Lead time stands as one of the most critical factors in chemical sourcing. Our standard production lead time for HEEBS ranges from two to four weeks ex-works, depending on our production schedule and current inventory. Demands can surge, especially around peak planning seasons, so we maintain buffer stocks but always flag possible longer delivery periods if demand rises sharply. Timing transparency allows your purchasing and logistics teams to plan around real production cycles—not speculative timelines.
The time needed for additional quality checks, special documentation, or combined shipping can add days; we communicate these clearly before final order confirmation. Emergency orders, while possible, sometimes create additional strain, so early engagement helps prevent last-minute surprises. Our plant teams coordinate closely with logistics and QA to ensure delivery matches our quoted schedule.
Our packaging options balance customer handling preferences, product safety, and bulk transport efficiency. Most product leaves our facility in 25 kg polyethylene-lined drum units, suited for manual handling and day-to-day plant use. For bulk users, we offer 500 kg or 1000 kg flexible intermediate bulk containers (FIBC, also known as big bags) with strong inner liners to prevent moisture ingress and dust generation.
Shipping in palletized cardboard boxes or custom containers for overseas consignments remains an option for long-haul export, designed around sea freight best practices and stable stacking in standard shipping environments. All packaging follows our self-developed traceability protocols and meets the regulatory expectations of our largest export markets.
With each order, our technical support team reviews packaging preferences to solve real-world problems: minimizing warehouse clutter, improving dispensing speed, and complying with receiving site safety standards. Experience on the shipping bay dock makes one point clear—proper packaging delivers more than convenience. It means fewer incidents and faster turnaround at both ends of the supply chain.
In practical terms, our decades of direct manufacturing have taught us that talking openly about MOQs, lead times, and packaging ensures the process runs smooth from factory line to final blending tank. We keep these discussions straight and adaptable, always looking for ways to streamline your sourcing without sacrificing chemical integrity or regulatory compliance.
We manufacture Hydroxyethyl Ethylene Bis Stearamide at our dedicated facility, following a thorough compliance and quality framework. Our shipments always include a full suite of regulatory and safety documents, starting with a comprehensive Safety Data Sheet (SDS). This document outlines hazards, safe handling, emergency measures, and disposal guidelines. We keep our SDS up to date, reflecting both international regulations and critical details from our latest production batches.
For markets within the European Union and clients requiring international certification, we support shipments with REACH compliance statements. Our technical staff maintain active REACH registrations wherever applicable, and we continuously monitor for updates due to changing chemical management regulations. We also document RoHS status for partners in electrical and electronic sectors, detailing absence of restricted substances as outlined in the Directive. Every document handed over is traceable to the actual batch and production lot, tying regulatory paperwork directly to the materials we deliver.
Certainty around compliance is never a guessing game from our end. Our quality management team provides Certificates of Analysis (CoA) for every shipment. Each CoA lists actual test results for parameters such as melting point, acid value, saponification value, and color. This approach is designed to maintain transparency with each client and ensure batch consistency. On request, we can issue statements regarding suitability for particular industrial uses, such as food contact, pending the required test regimes.
Production at our site follows established Good Manufacturing Practices. Our facilities and documentation workflows align with ISO 9001:2015 standards. We retain archival samples from production batches; this policy strengthens our ability to investigate, validate, or trace product quality even months after dispatch.
The physical form of Hydroxyethyl Ethylene Bis Stearamide, usually pastilles or microbeads, lends itself well to palletized shipments in lined bags or fiber drums. We select packaging to prevent moisture ingress and to protect the product from contamination on route. Each package is labeled with net weight, batch number, and manufacturing date for process visibility from warehouse to production floor.
Our material remains stable under normal ambient conditions. During storage and transit, we recommend keeping containers sealed, in a dry area, and out of direct sunlight. Temperature extremes do not degrade the additive under short-term exposure, but long periods above 40°C or below zero can cause caking or alter flow properties. We coordinate with our logistics partners to minimize exposure during ocean freight or long-haul delivery, ensuring that integrity remains intact from our site to your door.
Regulatory and operational standards in chemicals keep evolving. We treat documentation as a living process: our regulatory team routinely audits our declarations and file updates when regulations shift. Our clients receive fresh documentation on every new batch, ensuring shelf-life information, compliance statements, and quality certifications always reflect the latest data.
Comprehensive documentation and responsible logistics have always been a key component of our operation. By keeping direct control of every step—production, paperwork, packaging, and shipment—we build transparency and security into all commercial relationships. Our team responds directly to technical queries and can supply supporting documents tailored to specific regulatory filings or audits.
Clarity is non-negotiable in chemical manufacturing. By providing direct, detailed documentation and supporting our shipments with robust packaging and proactive follow-up, we help our customers remain confident in both compliance and quality from the factory floor to end use.
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
