1,4-Bis(Bromoethylketoneoxy)-2-Butene Bulk Price & COA Data

Procurement of 1,4-Bis(bromoethylketoneoxy)-2-butene requires precise validation of chemical identity and supply chain reliability. This brominated organic compound, identified by CAS 20679-58-7, serves as a critical intermediate and active agent in industrial water treatment and paper manufacturing. Buyers must evaluate bulk pricing structures against verified purity metrics rather than generic market claims. The following technical breakdown outlines volume discount mechanisms, analytical verification protocols, and storage parameters required for safe integration into existing chemical inventories.

1,4-Bis(bromoethylketoneoxy)-2-butene Bulk Price Tiers and Volume Discount Structures

Commercial pricing for this water treatment chemical is dictated by order volume, packaging configuration, and Incoterms. Standard procurement models typically segment pricing into drum, intermediate bulk container (IBC), and isotank quantities. Smaller volumes, such as 200kg drums, incur higher per-kilogram costs due to packaging labor and hazardous material handling fees. Transitioning to IBCs or bulk liquid shipments significantly reduces the unit price by optimizing logistics density. Manufacturers often apply tiered discounts once procurement thresholds exceed 1 metric ton, reflecting reduced administrative overhead per unit shipped.

FOB (Free on Board) and CIF (Cost, Insurance, and Freight) terms impact the landed cost substantially. For international shipments, CIF pricing includes marine insurance and freight to the port of discharge, providing cost certainty for the buyer. However, experienced procurement managers often prefer FOB terms to maintain control over freight forwarding and insurance claims. Volume commitments over 12-month contracts can secure fixed pricing, shielding operations from raw material volatility in bromine and butene derivatives. As a global manufacturer, NINGBO INNO PHARMCHEM CO.,LTD. structures these agreements to align with production cycles, ensuring consistent availability for continuous process industries.

Price negotiations should focus on purity guarantees rather than solely on base cost. Lower-priced batches often exhibit higher variance in bromine content or moisture levels, which can affect dosing calculations in final applications. Establishing a price matrix linked to GC-MS purity specifications ensures that cost reductions do not compromise process efficiency. Buyers should request a formal price schedule detailing breaks at 500kg, 1000kg, and 5000kg intervals to model total cost of ownership accurately.

Requesting Certificate of Analysis (COA) and CAS 20679-58-7 Verification

Verification of CAS 20679-58-7 is the primary step in validating supplier credibility. A robust Certificate of Analysis (COA) must accompany every batch, detailing specific analytical results rather than generic specification ranges. Key parameters include assay purity, moisture content, and identification via infrared spectroscopy (IR) or nuclear magnetic resonance (NMR). Procurement teams should mandate that the COA reflects actual batch data generated within 30 days of shipment. Generic COAs lacking batch-specific numbers indicate potential stock blending or insufficient quality control.

GC-MS (Gas Chromatography-Mass Spectrometry) data is critical for confirming the absence of unreacted intermediates such as bromoacetic acid or butenediol. High levels of residual acids can corrode storage tanks and dosing equipment, leading to unplanned maintenance costs. The COA should explicitly state the detection limit for these impurities, typically requiring levels below 0.5% for high-grade industrial applications. Verification also extends to physical properties; density measurements at 20°C should align with theoretical values to confirm structural integrity.

When auditing a supplier, request historical COA data for the previous three production runs. Consistency across batches demonstrates process stability and reduces the need for incoming quality assurance testing at the receiving facility. Discrepancies in purity greater than 1% between batches suggest unstable synthesis conditions. For critical applications, third-party verification via SGS or Eurofins provides an additional layer of security, ensuring the material matches the declared Biocide 20679-58-7 profile before it enters the production line.

1,4-Bis(bromoacetoxy)-2-butene Technical Specifications and Quality Assurance

Technical compliance relies on adherence to strict physicochemical parameters. The compound, also known synonymously as 1,4-Bis(bromoacetoxy)-2-butene, possesses specific characteristics that define its performance as a non-oxidizing biocide. Deviations in molecular weight or density can alter solubility profiles and reaction kinetics in formulation tanks. The table below compares standard industry specifications against typical high-quality production parameters.

Parameter	Standard Specification	Typical High-Grade Result	Test Method
CAS Number	20679-58-7	20679-58-7	Verification
Molecular Formula	C8H10Br2O4	C8H10Br2O4	Calculation
Molecular Weight	329.97 g/mol	329.95 - 330.00 g/mol	Mass Spec
Density (20°C)	1.77 g/cm³	1.76 - 1.78 g/cm³	ASTM D4052
Purity (GC-MS)	> 95.0%	> 98.5%	GC-MS
Moisture Content	< 1.0%	< 0.5%	Karl Fischer
Appearance	Colorless to Pale Yellow Liquid	Colorless Liquid	Visual

Quality assurance protocols at NINGBO INNO PHARMCHEM CO.,LTD. emphasize batch consistency to support downstream formulation stability. High purity levels minimize the introduction of extraneous organic load into water systems, which is crucial for maintaining biological control without exacerbating nutrient levels for microbial growth. For detailed product information and sourcing options, review the 1,4-Bis(bromoethylketoneoxy)-2-butene industrial slime control agent portfolio. Maintaining tight controls on moisture is particularly important, as hydrolysis can release bromoacetic acid, altering the pH balance of the stored product.

Industrial Biocide and Slimicide Applications for Water Treatment Compliance

This compound functions primarily as a slime control agent in industrial cooling towers and paper mill wastewater systems. Its mechanism of action involves penetrating microbial biofilms and disrupting cellular functions through alkylation. Unlike oxidizing biocides such as chlorine, this brominated ester remains effective in systems with high organic load where oxidizers are rapidly consumed. This makes it a preferred drop-in replacement for facilities seeking to reduce corrosion rates associated with halogen dosing.

In paper manufacturing, it controls microbial growth in white water systems, preventing slime deposits that cause sheet breaks and downtime. Effective dosing requires precise calculation based on system volume and turnover rate. Overdosing can lead to excessive chemical costs, while underdosing allows resistant strains to develop. To optimize efficacy, operators should consult the 1,4-Bis(bromoethylketoneoxy)-2-butene Water Treatment Formulation Guide for specific compatibility data with other treatment additives. Integration with dispersants and corrosion inhibitors must be validated to prevent precipitation or loss of activity.

Regulatory compliance in water discharge is a critical consideration. While this text does not address specific regional registrations, the chemical profile supports effective microbial control at lower concentrations compared to older generations of biocides. This efficiency reduces the total chemical load discharged into the environment. Facilities must monitor residual levels in effluent to ensure alignment with local environmental protection standards. The compound's stability in varying pH ranges allows for flexible application across different industrial processes without requiring extensive pH adjustment prior to dosing.

Global Bulk Procurement Logistics and Safe Storage Guidelines

Logistics for CAS 20679-58-7 require adherence to hazardous material transport regulations due to its chemical nature. The density of 1.77 g/cm³ classifies it as a heavy liquid, influencing stacking weights and pallet configurations during ocean freight. Containers must be tightly sealed to prevent moisture ingress, which can trigger hydrolysis. Storage areas should be cool, dry, and well-ventilated, away from incompatible materials such as strong oxidizing agents or bases. Temperature control is essential; excessive heat can accelerate decomposition, while freezing may alter physical handling properties.

Compatibility with storage tank materials is a vital safety parameter. Certain elastomers and polymers may degrade upon prolonged contact with brominated esters. Before installing new dosing pumps or lining storage tanks, engineering teams should review the 1,4-Bis(bromoethylketoneoxy)-2-butene Membrane Compatibility documentation to select appropriate seals and gaskets. Stainless steel 316 or lined carbon steel tanks are generally recommended for bulk storage. Personal protective equipment (PPE) including chemical-resistant gloves and eye protection is mandatory during handling to prevent skin irritation.

Supply chain resilience depends on diversified shipping routes and adequate safety stock levels. Lead times for bulk chemical shipments can vary based on port congestion and customs clearance procedures. Procurement strategies should account for a minimum of 4-6 weeks lead time for overseas shipments to prevent stockouts. Regular inventory audits ensure that older stock is rotated correctly, maintaining chemical potency. By aligning logistics planning with technical storage requirements, facilities can maintain a safe and efficient supply of this critical industrial fungicide and biocide component.

Effective chemical procurement balances technical specification adherence with strategic supply chain management. Ensuring high purity and proper handling maximizes the performance lifecycle of the product in industrial applications.

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