Material Options by Service

When considering plastic injection molding materials for your product there are many properties to consider. We have provided general characteristics for many of the commodity, engineering, and performance grade plastic materials to help guide you to the best material for your application. We are providing a 4 step guide to help with material selection.   1. Application – Begin with a thorough understanding of the product application. • Where it will be used? • How long it needs to last? • What environmental and mechanical conditions will the product be exposed? • What cosmetic or other performance characteristics do you desire for your product? • What economic or cost constraints do you have for your product?   2. Material Properties – To be able to effectively evaluate and select materials it is important to have a general understanding of plastic material mechanical performance, chemical resistance, environmental requirements and the technical standards used to measure performance. UL IDES provides an excellent resource to understand these properties. UL IDES Material Properties.   3. Select a material family – Once you have a good understanding of the application and material properties you can begin narrowing your search to a family of plastic resins. You can use the following charts to help narrow your search to a few materials or review summary descriptions of the most commonly specified materials in our Thermoplastic Material Guide below.   4. Specify Material – Use the UL IDES Materials resource to pull up manufacturers’ material data sheets to review specific materials and match their performance to best suit your application. Additional performance can be achieved by compounding materials with alloys, fillers, and additives. The Engineers at Shenyue Technology help guide our customers through the complex material selection process to find cost-effective solutions with the right performance characteristics.   We have selected some of the most common commodity, engineering and performance grade materials and are providing the following briefs and application sheets to help in selecting the best material for your application. If we can be of assistance with your project email us at sales@shenyueplastics.com or use our Contact Form.     Thermoplastic Material Selection Guide Commodity: Polypropylene Injection Molding (PP): PP is a low cost, lightweight polymer that has excellent chemical resistance. Polypropylene is tough, has good resistance to fatigue, and can be reinforced with glass fiber or minerals to enhance mechanical properties.   High Density Polyethylene (HDPE): A versatile, workhorse thermoplastic polymer ideal for consumer and industrial products, toys, storage containers, sporting goods, appliances, and milk crates.   Low Density Polyethylene (LDPE): LDPE is a softer version of HDPE and popular in manufacturing consumer and industrial products.   Polyvinyl Chloride (PVC): PVC is lightweight compared to metal pipe that it has replaced in many applications, but is heavier than most other grades of plastic. PVC is widely used in water, sewer, windows, siding, and other building products.   Polystyrene: Commonly used for office products, food processing and storage, consumer products, and construction.   High Impact Polystyrene (HIPS): HIPS is a versatile, economical, impact-resistant plastic.   Engineering: ABS Plastics Injection Molding: ABS is a common engineering thermoplastic that has good impact strength and toughness along with mechanical and electrical properties that make it ideal for a variety of plastic injection molding applications.   Acrylic Injection Molding (PMMA): Known commonly by the Plexiglas® and Lucite® trademarks, acrylic – or PMMA (polymethyl methacrylate) – is a glass substitute that offers many exceptional properties in plastic injection molding.   Nylon (PA): Few plastics combine the versatility, value, and mechanical performance of nylon. The most common forms of Nylon are the PA 6 and PA 66 versions. Nylon has excellent strength, stiffness, heat resistance, wear-resistance and lubricity, chemical resistance to hydrocarbon.   Thermoplastic Elastomer (TPE): Thermoplastic elastomer (TPE) combines the flexibility and elasticity of rubber with the processing advantages of plastics. It offers good impact resistance, soft touch, and excellent design flexibility, making it suitable for overmolding applications and products requiring enhanced grip or sealing performance. TPE is widely used in consumer products, automotive components, seals, and soft touch applications.   Thermoplastic Polyurethane (TPU): Thermoplastic polyurethane (TPU) is a durable elastomer with excellent abrasion resistance, flexibility, and mechanical strength. It is well suited for applications that require both elasticity and toughness, such as protective components, flexible parts, and wear resistant products.   Polycarbonate (PC): Polycarbonate is a rugged, engineering-grade thermoplastic that offers exceptional impact resistance and strength in many demanding applications, like bulletproof glass.   Polybutylene Terephthalate (PBT): A polyester resin, PBT offers good electrical, mechanical and thermal properties with excellent chemical resistance to a variety of chemicals including aliphatic hydrocarbons, oil, grease, dilute acids and bases, and detergents.   Performance: Polyphenylene Sulfide (PPS): PPS has the broadest resistance to chemicals of any engineered thermoplastic. PPS is exceptionally resistant to flame, acids, ketones, alkalis and hydrocarbons, making it an ideal thermoplastic for challenging corrosive, high-heat, and chemically strenuous environments.    

When selecting rubber materials for your product, it is important to consider performance requirements, environmental conditions, and cost factors. We provide a general overview of commonly used rubber materials to help guide you in choosing the most suitable material for your application.   1.Application Start by clearly understanding the application of your product: Will it be used indoors or outdoors? Does it require sealing, cushioning, or vibration resistance? Will it be exposed to heat, UV, chemicals, or oil? What level of flexibility or hardness is required? Are there any cost or lifespan requirements?   2. Material Properties Rubber materials vary significantly in performance. Key properties to consider include: Elasticity and flexibility Temperature resistance Chemical and oil resistance Weather and UV resistance Hardness and durability Understanding these properties will help you select the right material for your application.   3. Select a Material Type Based on your application and required properties, you can narrow down to a suitable rubber material family such as silicone, EPDM, or NBR.   4. Specify Material After selecting the material type, specific grades and formulations can be chosen to meet detailed performance and cost requirements. Our engineering team can assist in selecting the most suitable material based on your design and application.     Rubber Material Overview Natural Rubber (NR) Natural rubber offers excellent elasticity and flexibility, making it suitable for general purpose applications such as seals, vibration dampers, and basic industrial components.   Styrene Butadiene Rubber (SBR) SBR is a cost effective rubber with good abrasion resistance, commonly used in automotive and general industrial products.   Engineering Rubber EPDM Rubber EPDM provides excellent resistance to weathering, UV, and aging. It is widely used in outdoor applications such as seals, gaskets, and construction components.   Nitrile Rubber (NBR) NBR offers strong resistance to oils and fuels, making it ideal for automotive and industrial sealing applications.   Silicone Rubber (VMQ) Silicone rubber has outstanding heat resistance and flexibility across a wide temperature range. It is commonly used in medical, food grade, and high temperature environments.     Performance Rubber Fluoro Rubber (FKM / Viton) FKM provides exceptional resistance to high temperatures, chemicals, and oils. It is suitable for demanding environments such as automotive, aerospace, and industrial applications.   Hydrogenated Nitrile Rubber (HNBR) HNBR combines excellent mechanical strength with resistance to heat and chemicals, making it ideal for high performance sealing applications.

3D printing materials vary depending on the process and application. The most commonly used materials fall into the following categories:   Plastics (Most Common) PLA Easy to print, low cost, suitable for visual prototypes and basic models.   ABS Strong and durable, commonly used for functional prototypes and engineering parts.   PETG Good strength and chemical resistance, widely used for consumer and industrial parts.   Nylon (PA) High strength and wear resistance, ideal for functional and mechanical components.   Resin Materials (SLA) Standard Resin High detail and smooth surface, ideal for visual prototypes.   Engineering Resin Improved strength and heat resistance for functional testing.   Transparent Resin Used for optical or aesthetic applications requiring clarity.