{"id":12217,"date":"2026-02-10T16:59:04","date_gmt":"2026-02-10T08:59:04","guid":{"rendered":"https:\/\/dewintech.com\/blog\/how-describe-technical-specs-rfq-sourcing-plastic\/"},"modified":"2026-02-10T16:59:04","modified_gmt":"2026-02-10T08:59:04","slug":"wie-beschreibe-ich-technische-spezifikationen-rfq-sourcing-kunststoff","status":"publish","type":"post","link":"https:\/\/dewintech.com\/de\/blog\/how-describe-technical-specs-rfq-sourcing-plastic\/","title":{"rendered":"Wie beschreibt man technische Spezifikationen in einer RFQ bei der Beschaffung von kunststoffblasgeformten Teilen?"},"content":{"rendered":"

\n \"RFQ\n<\/p>\n

On our production floor, we see RFQs arrive daily. Some are crystal clear. Others leave our engineers guessing. The vague ones cause delays, misquotes, and costly rework. When sourcing blow molding parts, poor specs mean poor results.<\/p>\n

To describe technical specs in a blow molding RFQ, include exact dimensions with tolerances, material grade and properties, wall thickness ranges, mold design requirements, surface finish standards, annual volumes, and quality certifications. Provide 2D drawings and 3D CAD files for precise understanding.<\/strong><\/p>\n

This guide breaks down each critical specification area. You will learn what details matter most and how to communicate them clearly to suppliers.<\/p>\n

What material properties and resin grades should I specify for blow molding projects?<\/h2>\n

Our engineering team reviews hundreds of material specs each year 1<\/a><\/sup>. The most common problem? Buyers name a generic plastic type but skip the critical properties. This creates confusion and delays during quoting.<\/p>\n

Specify the exact resin grade, melt flow index, density, and any required additives. Include FDA compliance for food contact, UV stabilizers for outdoor use, and impact modifiers for durability. Name the manufacturer and grade number when possible to eliminate ambiguity.<\/strong><\/p>\n

\"Specify<\/p>\n

Why Resin Grade Matters More Than Plastic Type<\/h3>\n

Saying "HDPE" is not enough. HDPE comes in hundreds of grades. Each has different melt strength, drawability, and processing characteristics 2<\/a><\/sup>. A grade designed for injection molding may fail in blow molding. The parison needs specific melt properties to expand without thinning or rupturing 3<\/a><\/sup>.<\/p>\n

When we work with clients on open, black plastic carrying cases, we ask detailed material questions. What impact resistance does the case need? Will it face UV exposure? Does it require chemical resistance? These answers guide the resin selection.<\/p>\n

Key Material Properties to Include<\/h3>\n\n\n\n\n\n\n\n\n\n
Property<\/th>\nWhy It Matters<\/th>\nExample Specification<\/th>\n<\/tr>\n<\/thead>\n
Melt Flow Index (MFI)<\/a> 4<\/a><\/sup><\/td>\nControls parison formation and wall uniformity<\/td>\n0.3\u20130.5 g\/10min for large parts<\/td>\n<\/tr>\n
Density<\/td>\nAffects strength, stiffness, and chemical resistance<\/td>\n0.954\u20130.960 g\/cm\u00b3 for HDPE<\/td>\n<\/tr>\n
Melt Strength<\/td>\nPrevents parison sag during blow molding<\/td>\nHigh melt strength grade required<\/td>\n<\/tr>\n
Impact Resistance<\/td>\nDetermines drop test performance<\/td>\nNotched Izod \u2265 10 kJ\/m\u00b2<\/td>\n<\/tr>\n
UV Stabilizer<\/td>\nPrevents degradation in outdoor applications<\/td>\n0.5% UV stabilizer package<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

Food-Grade and Compliance Requirements<\/h3>\n

For food-contact applications, specify FDA 21 CFR compliance. For hazardous goods containers, include UN certification requirements. Our team in Vietnam processes many food packaging projects. We always confirm compliance documents before production starts.<\/p>\n

Sustainability is now a major factor. Many buyers require recycled content. Specify the percentage of post-consumer recycled (PCR)<\/a> 5<\/a><\/sup> or post-industrial recycled (PIR) material allowed. Note if the finished part must be recyclable in standard streams.<\/p>\n

Common Material Specification Mistakes<\/h3>\n

Vague color descriptions cause rework. Use Pantone numbers instead of "black" or "dark gray." Specify if carbon black is acceptable or if other pigments are required. For our black carrying case projects, we confirm the exact black shade and gloss level upfront.<\/p>\n

Omitting additive requirements leads to field failures. If the part needs anti-static properties, flame retardancy, or antimicrobial treatment, state it clearly in the RFQ.<\/p>\n

How do I define clear dimensional tolerances and wall thickness requirements in my RFQ?<\/h2>\n

In our experience exporting to the US, dimensional disputes rank among the top three quality issues. They happen when buyers expect injection molding precision from a blow molding process<\/a> 6<\/a><\/sup>. The two processes have fundamentally different capabilities.<\/p>\n

Define nominal dimensions, minimum wall thickness, and tolerance ranges appropriate for blow molding. Typical tolerances are \u00b10.5mm to \u00b12mm depending on part size. Specify critical-to-quality dimensions separately with tighter controls. Always provide both 2D drawings and 3D CAD files.<\/strong><\/p>\n

\"Dimensional<\/p>\n

Understanding Blow Molding Tolerance Realities<\/h3>\n

Blow molding creates parts by inflating a parison inside a mold. This expansion process cannot achieve injection molding precision. Wall thickness varies based on the blow-up ratio. Areas that stretch more become thinner.<\/p>\n

For a carrying case, corners and handle areas experience maximum stretch. These zones will have thinner walls than flat sections. Smart RFQ writers specify minimum acceptable thickness rather than demanding uniformity.<\/p>\n

Recommended Tolerance Ranges<\/h3>\n\n\n\n\n\n\n\n\n\n
Part Feature<\/th>\nStandard Tolerance<\/th>\nTight Tolerance<\/th>\nNotes<\/th>\n<\/tr>\n<\/thead>\n
Overall Length<\/td>\n\u00b11.5mm<\/td>\n\u00b10.8mm<\/td>\nDepends on part size<\/td>\n<\/tr>\n
Overall Width<\/td>\n\u00b11.5mm<\/td>\n\u00b10.8mm<\/td>\nCooling affects shrinkage<\/td>\n<\/tr>\n
Wall Thickness<\/td>\n\u00b115-20%<\/td>\n\u00b110%<\/td>\nSpecify minimum, not target<\/td>\n<\/tr>\n
Thread Dimensions<\/td>\n\u00b10.3mm<\/td>\n\u00b10.15mm<\/td>\nRequires precision tooling<\/td>\n<\/tr>\n
Flatness<\/td>\n1mm per 100mm<\/td>\n0.5mm per 100mm<\/td>\nFixture may be needed<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

Specifying Wall Thickness Correctly<\/h3>\n

Our engineers recommend this approach: state the minimum acceptable wall thickness for structural integrity. Let the supplier optimize the nominal thickness for process capability. This gives molders flexibility while protecting part performance.<\/p>\n

For a black plastic carrying case, we might specify:<\/p>\n

    \n
  • Minimum wall thickness: 2.0mm anywhere on the part<\/li>\n
  • Target wall thickness: 2.5mm nominal<\/li>\n
  • Maximum wall thickness: 3.5mm to control weight and shrinkage<\/li>\n<\/ul>\n

    Critical Dimensions vs. Reference Dimensions<\/h3>\n

    Not all dimensions matter equally. Mark critical-to-quality (CTQ) dimensions on your drawing. These get tighter tolerances and mandatory inspection. Reference dimensions guide overall shape but allow wider variation.<\/p>\n

    CTQ dimensions for a carrying case typically include:<\/p>\n

      \n
    • Latch mounting hole locations<\/li>\n
    • Hinge pin hole diameters<\/li>\n
    • Lid-to-base alignment features<\/li>\n
    • Handle attachment points<\/li>\n<\/ul>\n

      Shrinkage and Secondary Operations<\/h3>\n

      Blow molded parts shrink during cooling. Shrinkage varies by material, wall thickness, and cooling rate. HDPE typically shrinks 2-3%. Include shrinkage allowance in your tolerance stack-up.<\/p>\n

      If secondary operations like drilling or trimming follow molding, account for fixture accuracy. Post-molding operations add their own tolerance band.<\/p>\n

      What details regarding mold design and parting lines must I include to avoid defects?<\/h2>\n

      When we calibrate our blow molding processes, parting line placement determines success or failure. A poorly located parting line creates flash, weak seams, and visible defects. The RFQ must address this early.<\/p>\n

      Include parting line location preferences, pinch-off requirements, flash allowance specifications, and any cosmetic restrictions. Specify mold material, expected lifespan in shots, and cooling channel requirements. Define who owns the mold and maintenance responsibilities.<\/strong><\/p>\n

      \"Mold<\/p>\n

      Why Parting Line Location Matters<\/h3>\n

      The parting line is where two mold halves meet. At this junction, excess material (flash) forms. The parison gets pinched off here. A weak pinch creates a potential failure point under stress.<\/p>\n

      For carrying cases, we typically recommend placing the parting line along the perimeter edge. This hides the seam visually and positions it away from high-stress areas. The RFQ should specify acceptable and prohibited parting line zones.<\/p>\n

      Mold Material and Lifespan Specifications<\/h3>\n\n\n\n\n\n\n\n
      Mold Material<\/th>\nTypical Lifespan<\/th>\nBest For<\/th>\nCost Level<\/th>\n<\/tr>\n<\/thead>\n
      Cast Aluminum<\/td>\n50,000\u2013100,000 shots<\/td>\nLow-medium volume<\/td>\nLow<\/td>\n<\/tr>\n
      Billet Aluminum<\/td>\n100,000\u2013500,000 shots<\/td>\nMedium-high volume<\/td>\nMedium<\/td>\n<\/tr>\n
      Steel<\/td>\n500,000+ shots<\/td>\nHigh volume, abrasive materials<\/td>\nHigh<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

      Your RFQ should state expected annual volume and total lifetime volume. This guides mold material selection. Over-specifying mold quality wastes money. Under-specifying causes premature wear.<\/p>\n

      Cooling Channel Requirements<\/h3>\n

      Cooling affects cycle time, dimensional stability, and surface quality. Advanced cooling uses gundrilled water channels close to the cavity surface. Standard cooling uses drilled passages further from the surface.<\/p>\n

      For tight tolerances on a carrying case, specify chilled mold surfaces. Water temperature around 50-60\u00b0F reduces cycle time and improves dimensional control. State if the supplier must design cooling or if you provide the layout.<\/p>\n

      Flash and Pinch-Off Standards<\/h3>\n

      Flash is unavoidable in blow molding. Your RFQ defines how much is acceptable and where. Common specifications include:<\/p>\n

        \n
      • Maximum flash thickness: 0.3mm<\/li>\n
      • Flash removal method: trimmed flush, no burrs<\/li>\n
      • Pinch-off strength: must pass drop test without separation<\/li>\n
      • Cosmetic zones: no visible flash or trimming marks<\/li>\n<\/ul>\n

        Mold Ownership and Maintenance<\/h3>\n

        Clearly state who owns the mold after production. In our contracts, clients typically own the mold but we store and maintain it. Define maintenance responsibilities, including:<\/p>\n

          \n
        • Who pays for preventive maintenance?<\/li>\n
        • What triggers major repair vs. replacement?<\/li>\n
        • How long must the supplier store the mold between orders?<\/li>\n
        • What happens to the mold if the business relationship ends?<\/li>\n<\/ul>\n

          Secondary Equipment Considerations<\/h3>\n

          Blow molding requires more than just the main mold. Trimming fixtures, drilling jigs, and inspection gauges add cost. A complete RFQ lists all required secondary tooling. Missing this causes budget surprises.<\/p>\n

          How should I describe surface finish and texture expectations for the final part?<\/h2>\n

          Our production team has rejected parts that met every dimensional spec but failed visual inspection. Surface finish is subjective without clear standards. Your RFQ must eliminate guesswork.<\/p>\n

          Describe surface finish using industry standards like SPI or VDI classifications. Specify gloss level, texture pattern, acceptable defect types and sizes, and any logo or marking requirements. Provide physical samples or reference parts when possible for visual alignment.<\/strong><\/p>\n

          \"Surface<\/p>\n

          Industry Standards for Surface Finish<\/h3>\n

          Surface finish in plastics uses several classification systems. The most common are SPI (Society of the Plastics Industry) and VDI (German engineering standard). Using these standards removes ambiguity.<\/p>\n\n\n\n\n\n\n\n\n
          SPI Grade<\/th>\nDescription<\/th>\nTypical Application<\/th>\n<\/tr>\n<\/thead>\n
          A-1 to A-3<\/td>\nHigh gloss, mirror finish<\/td>\nCosmetic displays<\/td>\n<\/tr>\n
          B-1 to B-3<\/td>\nSemi-gloss<\/td>\nConsumer products<\/td>\n<\/tr>\n
          C-1 to C-3<\/td>\nMatte, fine texture<\/td>\nIndustrial parts<\/td>\n<\/tr>\n
          D-1 to D-3<\/td>\nTextured, coarse<\/td>\nGrip surfaces, non-cosmetic<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n

          For a black plastic carrying case, a C-2 or D-1 finish typically works well. The texture hides fingerprints and minor scratches during use.<\/p>\n

          Specifying Texture Depth and Pattern<\/h3>\n

          Texture is applied to the mold surface through chemical etching, EDM, or sandblasting. Deeper textures hide defects better but require more draft angle for part ejection.<\/p>\n

          Include these texture specifications:<\/p>\n

            \n
          • Texture depth: typically 0.02\u20130.10mm<\/li>\n
          • Pattern type: leather grain, geometric, random matte<\/li>\n
          • Texture supplier and pattern number if replicating existing design<\/li>\n
          • Draft angle requirement based on texture depth<\/li>\n<\/ul>\n

            Defect Acceptance Criteria<\/h3>\n

            No molded part is perfect. Your RFQ must define acceptable vs. rejectable defects. Common blow molding defects include:<\/p>\n

              \n
            • Parison lines<\/strong>: Faint lines from parison formation<\/li>\n
            • Weld lines<\/strong>: Visible seams where material flows meet<\/li>\n
            • Sink marks<\/strong>: Depressions from thick sections<\/li>\n
            • Black specks<\/strong>: Contamination from degraded material<\/li>\n
            • Scratches<\/strong>: Handling damage from mold or post-processing<\/li>\n<\/ul>\n

              For each defect type, specify:<\/p>\n

                \n
              • Maximum acceptable size (e.g., scratches \u22645mm length)<\/li>\n
              • Maximum quantity per part (e.g., \u22643 specks per surface)<\/li>\n
              • Zone restrictions (e.g., no defects on top surface)<\/li>\n<\/ul>\n

                Gloss Level Measurement<\/h3>\n

                Gloss is measurable with a gloss meter. Specify the measurement angle (usually 60\u00b0) and acceptable range. For matte finishes, gloss under 30 GU (gloss units) is typical. Semi-gloss ranges 30-70 GU. High gloss exceeds 70 GU.<\/p>\n

                Black parts show gloss variation more than light colors. For our carrying case projects, we specify gloss tolerance of \u00b15 GU to ensure batch consistency.<\/p>\n

                Logo and Marking Requirements<\/h3>\n

                If the part includes molded-in logos, text, or markings, provide vector artwork files. Specify:<\/p>\n

                  \n
                • Raised or recessed marking<\/li>\n
                • Depth or height of marking<\/li>\n
                • Location with dimensional tolerances<\/a> 7<\/a><\/sup><\/li>\n
                • Font and minimum character size<\/li>\n<\/ul>\n

                  Some buyers require date codes or cavity identification. Define the format, location, and whether it should be visible or hidden.<\/p>\n

                  Conclusion<\/h2>\n

                  A complete blow molding RFQ covers materials, dimensions, tolerances, mold design, and surface finish. Clear specifications prevent misquotes and rework. Take time to get your RFQ right before sending.<\/p>\n

                  Footnotes<\/h2>\n


                  \n1. Explains FDA compliance for plastics in food contact applications.                   \u21a9\ufe0e<\/a>
                  \n<\/span><\/p>\n


                  \n2. Discusses the initial consideration of parting line location in blow mold design.                   \u21a9\ufe0e<\/a>
                  \n<\/span><\/p>\n


                  \n3. Details industry standards for plastic surface finishes, including SPI and VDI.                   \u21a9\ufe0e<\/a>
                  \n<\/span><\/p>\n


                  \n4. Defines Melt Flow Index and its significance for thermoplastic polymers.                   \u21a9\ufe0e<\/a>
                  \n<\/span><\/p>\n


                  \n5. Provides a clear definition of post-consumer recycled materials in packaging.                   \u21a9\ufe0e<\/a>
                  \n<\/span><\/p>\n


                  \n6. Provides a comprehensive overview of the blow molding manufacturing process.                   \u21a9\ufe0e<\/a>
                  \n<\/span><\/p>\n


                  \n7. Explains engineering tolerances and their importance in manufacturing processes.                   \u21a9\ufe0e<\/a>
                  \n<\/span><\/p>\n