During a fire, ECCOH formulations eliminate the production of corrosive gas and toxic fume emissions, and generate a low amount of smoke, meaning they meet the highly demanding Euroclass designations—Class B2ca and Cca—as well as being suitable for other classes such as Dca or Eca. Optical fiber sheathing1 5924 UV 3.9 11.5 170 39 Dca Medium char formation, high flame retardancy, UV resistance and good Optical fiber sheathing1 5501 UV 11.0 11.5 170 35 Dca Easy processing and enhanced UV resistance. Optical Fiber Insulation 6151 6.0 17 160 33 Low thickness, gel resistant material for micro-modules or tight buffer running at ultra-high speed.

Weight Reduction • LFT has lower density vs. metal, but still meets structural performance requirements • Lightweighting helps meet sustainability goals related to lower fuel consumption and extended vehicle range Design Flexibility • Injection molding allows for complex geometries and part consolidation • Advanced modeling and computer-aided engineering (CAE) tools for long fiber composites help validate and optimize part design APPLICATION BULLETIN COMPARING PRODUCTION COST DRIVERS Cast Metal Stamped Metal Long Fiber Composite Material typically used Aluminum Steel Various base resins based on environmental conditions Casting X Stamping X Injection Molding X Machining X Not typically needed as LFT is a one-step process Drilling X Welding X Surface Treatments X X po st -p ro ce ss pr oc es s MATERIAL CHARACTERISTICS Characteristic Long Fiber Composite Aluminum Steel Specific Gravity (g/cc) 1.03–1.71 2.76 7.8–7.9 Specific Strength (Strength-to-Weight ratio) Excellent Good Poor Stiffness Fair Good Excellent Toughness/Fatigue Excellent Fair Fair Creep Good Excellent Excellent Corrosion Resistance Excellent Good Poor Temperature Range Performance Good Excellent Excellent Cycle Time Excellent Good Poor Design Freedom (i.e., complex geometry, part consolidation) Excellent Fair Fair Raw Material Cost Poor Good Fair Total Production Cost Good Fair Fair pr od uc ti on pe rf or m an ce Avient offers a range of customizable long fiber reinforced structural material solutions and design support for your metal-to-plastic conversion projects

PolyOne Develops High-Performing Plasticizer Alternative for Flexible PVC Chemical & Corrosion Resistant Formulations New Life for Aging Pipe

Each one specifies its own fire hazard tests and fail/pass criteria, which depend on the fire resistance required for the plastic part. ONCOLOR™ UL 94 COLORANTS HOW TO USE THE TABLES UL HB GENERIC RESIN TYPE FLAME MINIMUM THICKNESS MAXIMUM LET-DOWN Acetal Copolymer (POM) HB 1.50 1:20 Acrylonitrile Butadiene Styrene (ABS) HB 1.50 1:10 Ethylene Propylene Thermoplastic Rubber (EPTR) HB 1.50 1:20 High Impact Polystyrene (HIPS) HB 1.50 1:10 Liquid Crystal Polymer (LCP) HB 0.83 1:10 Polyamide (PA) HB 3.20 1:33 Polyamide (PA66 and PA 4/6) HB 0.81 1:20 Polyamide 6 (PA6) HB 0.75 1:25 Polyamide 66 (PA66) HB 0.40 1:40 Polybutylene Terephthalate (PBT) HB 0.81 1:20 Polybutylene Terephthalate/Polycarbonate (PBT/PC) HB 1.50 1:10 Polycarbonate (PC) HB 1.50 1:15 Polycarbonate/Acrylonitrile Butadiene Styrene (PC/ABS) HB 1.50 1:20 Polycarbonate/Polyethylene Terephthalate (PC/PET) HB 1.50 1:20 Polyethylene (PE) HB 1.50 1:50 Polyethylene Terephthalate (PET) HB 0.80 1:16.7 Polyketone HB 1.50 1:20 Polymethyl Methacrylate (PMMA) HB 3.00 1:25 Polypropylene (PP) HB 1.50 1:15 Polystyrene (PS) HB 0.83 1:15 Polyurethane (PUR) HB 1.50 1:25 Polyvinylchloride (PVC) HB 1.50 1:20 Styrene Acrylonitrile (SAN) HB 1.50 1:20 Thermoplastic Elastomer (TPE) HB 0.75 1:25 ASCEND GENERIC MINIMUM THICKNESS FLAME MAXIMUM LET-DOWN Polyamide 66 21X1(a)(f2), 21SPC1(a)(f2), 21SPF1(a)(f2), 21SPG1(a)(f2), 21SPM1(a)(f2), 20NSP1(a)(f2) 0.75 V-2 1:40 22HSP(e) 0.75 V-2 1:40 64C-R 3.0 V-2 1:50 ECO366(e) 0.4 V-0 1:40 ECO366H(e) 0.2 V-0 1:25 FR350J 0.4 V-0 1:25 20NSP(a)(f2), 21SPF(a)(f2), 21SPM(a)(f2), 21SPC(a)(f2) 0.4 V-2 1:40 20NSP(a)(h)(f2), 21SPF(a)(h)(f2), 21SPM(a)(h)(f2), 21SPC(a)(h) (f2) 1.5 V-2 1:20 Polyamide 66/6 (PA66/6) ECO315(e), ECO315J(e) 0.4 V-0 1:40 M344 3.0 V-0 1:25 909 0.75 V-0 1:25 BASF GENERIC MINIMUM THICKNESS FLAME MAXIMUM LET-DOWN Polyamide 6 8202(t1), 8202 Blend (t1) 0.71 V-2 1:25 8202C(t1), 8202C BLEND (t1) 1.50 V-2 1:25 8202CHS(t1) (t3), 8202C HS Blend 1.50 V-2 1:25 8202HS(t1) 1.50 V-2 1:25 B3S 0.80 V-2 1:25 B3S Q661 1.50 V-2 1:25 B3S R03 1.50 V-2 1:25 8232G HSFR(t9), B3U10G5 (t9) 1.50 V-0 1:25 Polyamide 6/66 (PA6/66) C3U (m) 0.40 V-0 1:25 KR4205(m), C3U (m), C3U (t)(m) 0.40 V-0 1:25 KR4205, C3U 0.40 V-0 1:25 Polyamide 66 1000(b), 1310-(b), Ultramid A3K Q603(+) 1.50 V-2 1:10 A3K (o) Q790(g)(f2) 0.41 V-2 1:20 A3K(f2), A3K Q601(f2) 0.41 V-2 1:20 A3SK 0.41 V-2 1:25 A5 3.00 V-2 1:33 A3W(f1), A3W FC (f1) 0.75 V-2 1:10 A3K R01 (t)(g)(f2) 0.40 V-2 1:20 Polybutylene Terephthalate B4406 G2 (o) Q798 1.50 V-0 1:20 B4406 G2(a), B4406 G2 (o) Q717(a) 1.50 V-0 1:20 B4406 G3 (o) Q798 1.50 V-0 1:20 B4406 G3(a), B4406 G3 (o) Q717(a) 1.50 V-0 1:20 B4406 G4 (o) Q798 1.50 V-0 1:20 B4406 G4(a2), B4406 G4 (o) Q717(a2) 1.50 V-0 1:20 B4406 G6 (o) Q798 3.00 V-0 1:12.5 B4406 G6(%) 1.50 V-0 1:20 B4406 G6(a1), B4406 G6 (o) Q717(a1), B4406 G6 (o) Q717 High Speed(a1) 1.50 V-0 1:20 B4406(a), B4406 (o) Q717(a) 1.50 V-0 1:20 B4406@ 1.50 V-0 1:20 B4450 G5, B4450 G5 (t) 0.40 V-2 1:50 Polyurethane (PUR) 11 85 A(a) FHF 000 (f2) 0.75 V-0 1:33 CELANESE GENERIC MINIMUM THICKNESS FLAME MAXIMUM LET-DOWN Liquid Crystal Polymer (LCP) A130(+), MT1310 1.50 V-0 1:40 Polyamide (PA) 132F(+)(f1), 135F(+)(f1) 0.75 V-2 1:20 HTNFR42G30NH 0.40 V-0 1:25 Polyamide 6/12 (PA6/12) 151, 151L 1.50 V-2 1:25 Polyamide 66 A3 GF 25 V0XI 0.40 V-0 1:25 101(r9)(f1), 101F(r9)(f1), 101L(r9)(f1) 0.75 V-2 1:20 103FHS(+), 103HSL(+) 0.75 V-2 1:20 FR50(+)(f1) 0.35 V-0 1:20 FR7025V0F(+) 0.50 V-0 1:33 Polyamide 66/6 (PA66/6) FR72G25V0 0.80 V-0 1:25 Polyamide 66/6T (PA66/6T) FR95G25V0NH 0.40 V-0 1:25 HTNFR52G30BL(r3) 0.75 V-0 1:33 HTNFR52G30L(+), HTNFR52G30(+) 0.75 V-0 1:33 HTNFR52G30NH(r6) 0.40 V-0 1:25 0.75 V-0 1:10 HTNFR52G35BL 0.75 V-0 1:25 HTNFR52G35(+), HTNFR52G35 0.75 V-0 1:33 Polyamide 6T/ MPMDT HTNFR51G35L(+) 0.81 V-0 1:33 Polybutylene Terephthalate 2016(b) 1.50 V-0 1:20 3116(b) 1.50 V-0 1:20 3216(b) 1.50 V-0 1:20 3316(b) 1.50 V-0 1:20 3316HF 1.50 V-0 1:20 LW9030FR 1.50 V-0 1:25 T841FR (r4) 1.50 V-0 1:25 Polyethylene Terephthalate (PET) FR530(l)(+)(f1), FR530L(l)(+)(f1) 0.75 V-0 1:25 Thermoplastic Elastomer (TPE) HTR8068 1.60 V-0 1:25 DOMO GENERIC MINIMUM THICKNESS FLAME MAXIMUM LET-DOWN Polyamide (PA) J 60X1 V30 0.40 V-0 1:25 Polyamide 6 PSB 286 0.80 V-2 1:25 3.00 V-2 1:25 S 60X1 V30 0.75 V-0 1.25 Polyamide 66 A 205F(r4) 0.38 V-2 1:25 A 225F 0.75 V-2 1:25 A 50H1 (r3)(f2) 0.40 V-0 1:25 A 30G1 0.40 V-0 1:25 COVESTRO GENERIC MINIMUM THICKNESS FLAME MAXIMUM LET-DOWN Polycarbonate 2407 + (z)(f1) 0.75-2.60 V-2 1:10 2807 + MAS183 0.75 V-2 1:25 6455 + (z) 6485 + (z)(f1) 1.50 V-0 1:25 Acrylonitrile Butadiene Styrene FR110 + 1.50 V-0 1:33 FR3005 HF + (z), FR3005 HF + BBS314 1.50 V-0 1:12.5 FR3010 + (z) 1.50 V-0 1:25 FR3010 HF + 3.00 V-0 1:25 FR3030 + 3.00 V-0 1:25 ENVALIOR GENERIC MINIMUM THICKNESS FLAME MAXIMUM LET-DOWN Polyamide 46 (PA46) TE250F6(h1)(j) 0.50 V-0 1:25 Polyamide 6 F223-D(f1), F223-D /A(f1) 0.75 V-2 1:25 K222-KGV5(f1) 0.75 V-2 1:16.7 1.50 V-2 1:16.7 K-FKGS6/B(f1)(y) 0.80 V-0 1:25 Polyamide 66 (PA66) SG-KGS6/HV 0.75 V-0 1:25 Thermoplastic Elastomer (TPE) PL460-S 1.60 V-0 1:25 Polyamide 4T (PA4T) T11 (h) 0.40 V-0 1:20 EXXONMOBIL LANXESS GENERIC MINIMUM THICKNESS FLAME MAXIMUM LET-DOWN Ethylene Propylene Thermoplastic Rubber (EPTR) 251-80W232(f7) 1.50 V-2 1:20 251-92W232 1.50 V-0 1:20 251-70W232 1.00 V-2 1:10 GENERIC MINIMUM THICKNESS FLAME MAXIMUM LET-DOWN Polyamide 6 B30S+(f1) 1.50 V-2 1:25 B31SK+ 1.50 V-2 1:25 Polybutylene Terephthalate B4235+ 1.50 V-0 1:10 TP364-302+, BF4232+(f1) 0.75 V-0 1:25 GENERIC MINIMUM THICKNESS FLAME MAXIMUM LET-DOWN Polybutylene Terephthalate 310(w) 1.50 V-0 1:20 310SE0(w) 1.50 V-0 1:20 310SE0(w),310SE0R(w) 1.50 V-0 1:20 420SE0(f1)(w)(GG)(rr1) 1.50 V-0 1:20 420SE0(f1)(w)(GG)(rr2) 1.50 V-0 1:20 457(w) 1.50 V-0 1:20 457(w), 451(w) 1.50 V-0 1:20 553(a)(f1)(w) 1.50 V-0 1:20 553(a)(f1)(w), 553E(a)(f1)(w), 553U(a)(f1)(w) 1.50 V-0 1:20 553(w)(f1), 553M(w)(f1) 1.50 V-0 1:20 DR48(w) 1.50 V-0 1:20 DR48,DR48M 1.50 V-0 1:20 V4760(a2) 0.40 V-0 1:20 EXVX1259, ENH4550 0.40 V-0 1:20 771 0.75 V-0 1:25 Polybutylene Terephthalate/ Polycarbonate (PBT/PC) 357(f1)(w)(IC), 357M(f1)(w)(IC), 357U(f1)(w)(IC) 1.50 V-0 1:20 357(f1)(w)(IC), 357U(f1)(w)(IC) 1.50 V-0 1:20 357X(f1) 1.50 V-0 1:20 V3900WX(GG)(f1)(IA), V3901WX(GG)(f1)(IA) 3.00 V-0 1:20 1.50 V-0 1:20 357(w)(f2)(IC), 357M(w)(f2)(IC), 357U(w)(f2)(IC) 1.50 V-0 1:20 GENERIC MINIMUM THICKNESS FLAME MAXIMUM LET-DOWN Polycarbonate 221(f2) 1.50 V-2 1:25 221R(f2) 1.50 V-2 1:25 500(f2), 500R(f2) 3.00 V-0 1:33 503(f1) 3.00 V-0 10:1 1.50 V-0 10:1 503(f1), 503R(f1) 3.00 V-0 10:1 1.50 V-0 10:1 943(ab) 1.50 V-0 1:20 943(f1) 1.50 V-0 1:20 943(f1), 923(f1) 1.50 V-0 1:20 950A, 920ASR, FXD911A(GG), 940ASR 1.50 V-2 1:25 CFR7630(f1)(gg*) 1.50 V-0 1:25 ML5139R(f2) 3.00 V-0 1:33 950A, FXD911A(GG), 940ASR 3.00 V-0 1:25 943 1.50 V-0 1:20 920A Acrylonitrile Butadiene Styrene C2950 1.50 V-0 6:100 C6200(GG) 2.00 V-0 1:20 Acrylonitrile Styrene Acrylate/ Polycarbonate (ASA/PC) HRA222 (GG) 0.80 V-2 1:20 SOLVAY (SYENSQO) GENERIC MINIMUM THICKNESS FLAME MAXIMUM LET-DOWN Polyphenyl Sulfone (PPSU) R-5100 (r1)(##), R-5000 (r1)(##) 1.50 V-0 1:10 Polyphthalamide (PPA) AFA-4133 V0(+) (*) 0.75 V-0 1:25 BASE RESIN GENERIC SPECIFIC MINIMUM THICKNESS FLAME MAXIMUM LET-DOWN ALBIS Polypropylene (PP) PP 13 CV2 14 1.50 V-2 1:25 AVIENT Polyvinylchloride M3700(X), M3755(X) 1.50 V-0 1:25 M3900 1.50 V-0 1:25 CHI MEI Acrylonitrile Butadiene Styrene (ABS) PA-765(+) 1.50 V-0 1:10 Acrylonitrile Butadiene Styrene PC-510(+) 1.50 V-0 1:25 EMS-CHEMIE Polyamide 6 (PA6) Grilon A 26 V0 0.75 V-0 1:25 FORMOSA Polycarbonate (PC) #1700+(f2) 0.36-0.42 V-2 1:50 GEON Polyvinylchloride 85891(f1) 1.70 V-0 1:20 85891(f2) 1.70 V-0 1:20 M3700(X) 1.50 V-0 1:25 M3900 1:25 INEOS Polystyrene (PS) 855 HV 3.00 V-1 100:4 INVISTA Polyamide 66 FRU4800 XHL (r1) 0.40 V-0 1:25 U4820L (r1) 0.40 V-2 1:25 BASE RESIN GENERIC SPECIFIC MINIMUM THICKNESS FLAME MAXIMUM LET-DOWN KINGFA Polyamide 66 (PA66) PA66-R11G25 (##) 0.25 V-0 1:25 KURARAY Polyamide 9T (PA9T) GP2300S 0.40 V-0 1:25 LG CHEM Acrylonitrile Butadiene Styrene LUPOY GP-5106-F 3.00 V-0 1:20 LOTTE CHEMICAL Acrylonitrile Butadiene Styrene (ABS) VH-0800(+) 1.50 V-0 1:25 Polycarbonate (PC) HN-1064(+) 0.75 V-2 1:10 1.20 V-1 1:10 Polystyrene (PS) VH-1800+ 1.50 V-0 1:25 MITSUBISHI Polycarbonate (PC) S-2000+(f1) 1.50-1.80 V-2 1:10 POLYMER PRODUCTS Polystyrene (PS) ZYNTAR 351 2.00 V-0 1:20 1.50 V-0 1:20 ZYNTAR 7000 2.00 V-0 1:25 ZYNTAR 702 2.00 V-0 1:25 8020 2.00 V-0 1:20 8120 2.00 V-0 1:20 8130 1.50 V-0 1:20 POLYMER RESOURCES Polycarbonate PC-FR1A-D, PC- FR2A-D, PC-FR3A-D 3.00 V-0 1:33 1.50 V-2 1:33 SUMITOMO Liquid Crystal Polymer (LCP) E6007LHF(ra) 0.30 V-0 1:25 E6007LHF-MR(gt) 0.20 V-0 1:12.5 BASE RESIN GENERIC SPECIFIC MINIMUM THICKNESS FLAME MAXIMUM LET-DOWN TORAY Polyamide 6 (PA6) 1017 1.60 V-2 1:16.5 Polyamide 66 3004-V0(rr), CM3004-V0(rr) 0.40 V-0 1:25 TRINSEO Polycarbonate (PC) 891(w) 1.10 V-0 1:25 WELLMAN Polyamide 66/6 (PA66/6) 220-N, 21L-N, 22L-N 1.50 V-2 1:25 WESTLAKE Polyvinylchloride 6597(f1), HF-6597(f1) 1.50 V-0 1:25 SP-7107 (f1)(a) 3.00 V-0 1:25 5VA AND 5VB BASE RESIN GENERIC SPECIFIC MINIMUM THICKNESS FLAME RATING COLORS MAXIMUM LET-DOWN AVIENT Polyvinylchloride (PVC) M3900 1.50 5VB ALL 1:25 WHITE 1:10 CELANESE Polyamide 66/6T (PA66/6T) FR95G25V0NH 1.50 5VA ALL 1:25 Polybutylene Terephthalate LW9030FR 2.00 5VA BLACK 1:25 3.00 5VA ALL 1:25 SK642FR 1.50 5VA BLACK 1:25 COVESTRO Acrylonitrile Butadiene Styrene FR3010 + (z) 3.00 5VA ALL 1:25 GEON Polyvinylchloride (PVC) M3900 1.50 5VB ALL 1:25 WHITE 1:10 Polybutylene Terephthalate/ Polycarbonate (PBT/PC) V3900WX(GG)(f1)(IA), V3901WX(GG)(f1)(IA) 3.00 5VA ALL 1:20 1.844.4AVIENT www.avient.com Copyright © 2024, Avient Corporation.

It works by injecting liquid color at high pressure into the polymer melt- flow between the end of the extruder, or melt-pipe, and the spin head. LIQUID FIBER PRODUCT FEATURES Fiber Solution Services LABORATORY PERFORMANCE BASED ON STATE-OF-THE-ART TECHNOLOGY To ensure the highest quality products, our customers rely on high-performance raw materials which guarantee that the final products meet the required specifications for heat resistance, household washing, weathering and lightfastness.

TARGET APPLICATIONS Excelite IM chemical foaming additives (CFAs) are engineered for a wide range of injection molded polymers: olefins, PVC, polystyrene, PC/ABS and high heat applications. PP, PE, PS, PVC No Good Foam PP Better, larger cells with lower cell density in standard IM processes; suitable for cell nucleation in structural foam processing PP, PE, PS, PVC Yes Better FA-110 Best cell structure with higher cell density; provides better structural integrity and lower density in standard IM processes PP, PE, PS, PVC Yes Best KEY CHARACTERISTICS Excelite IM formulations provide injection molders with: • Material density and weight reduction • High concentration of active CFA • Improved distribution of CFA into polymer matrix • High cell density with tight cell structure • Control over consistency and accuracy • Reduced sink marks • Ability to improve flow of material • Cycle time reduction • Improved dimensional stability • Improved thermal insulation EXCELITE IM – PRODUCT FORMULATIONS www.avient.com Copyright © 2020, Avient Corporation.

PRODUCT SELECTION & INSTALLATION GUIDE COMPOSITE SPRINGS VIBRATORY CONVEYORS AND SEATING FEATURE BENEFIT • Exceptional fatigue resistance • Corrosion resistance • Creep resistance Fewer failures for longer spring life, less frequent replacement, and a more reliable end product • High strength-to-weight ratio—less than half the weight of steel • High spring rate and deep deflection • Custom designs to support off-axis loads Stronger springs can mean fewer are needed in an application for overall cost savings • Common sizes in inventory • Custom design and finishing capabilities Fast, dependable service, ready-to-install product and customization options to boost your manufacturing efficiency PRODUCT DESCRIPTION Thermoset composite springs from Avient are engineered with proprietary vinyl ester or epoxy resins and unidirectional fiber reinforcement technologies. USES & APPLICATIONS Sorting and conveying equipment, such as: • Raw and processed food • Mined/quarried rock, ore, coal, sand • Pharmaceutical products • Powder • Forestry products • Agricultural products • Recycled materials Furniture, including indoor and outdoor seating Other applications requiring high cyclic fatigue resistance, repeatability and high performance including high temperature applications up to 300°F (149°C).

THERMOSET ADVANCED COMPOSITE TECHNOLOGIES PRODUCT SELECTION GUIDE Gordon Composites™ thermoset composite barstock, laminates, and hybrid composites made with proprietary resin/fiber reinforcement technologies offer: • Corrosion resistance • High fatigue strength • Deep deflection • Excellent interlaminar shear strength Our customized finishing capabilities include machining, water-jet cutting, profiling/shaping, sanding, slitting, laminating, molding and coatings. Benefits include: • Alternating longitudinal (axial) fibers for flexural & tensile strength and circumferential (biaxial) fibers for crush & burst resistance • Manufactured continuously, at a much higher rate than standard filament winding • Resin matrix and fiber loading formulated to meet your property requirements • Tubing in standard or customized diameters and lengths STANDARD SIZES To learn more about Avient advanced composite solutions, call +1.844.4AVIENT or visit www.avient.com/composites Copyright © 2020, Avient Corporation.

Plastic Piping System Flapper Valve - Case Study Gravi-Tech™ density modified formulations replaces brass in pipe valve

Plastic Piping System Flapper Valve - Case Study Gravi-Tech™ density modified formulations replaces brass in pipe valve