China supplier China Factory Manufacturer Precision PEEK Plastic Injection Molding Part Component for Machinery injection moulding for parts

Model Number: IDL-PEEK Injection-005
Plastic Modling Type: injection
Processing Service: Moulding
Pump Parts & Accessries: Injection Molding Part
Standard or Nonstandard: Nonstandard
Color: Nature, black, etc
Material: PEEK, PPS, Nylon, POM, etc
Size: OEM/ODM/Drawing
Temperature resistance: -60~300℃
Processing Type: Molding Injection
Tolerance: +-0.05mm
Delivery time: 7-15 days
Packaging: As the standard packaging
Packaging Details: Inner packaging in polybags and cartons
Port: HangZhou/HangZhou

PEEK propertyPEEK is a semi-crystalline,show high stiffness and hardness. and an unique high tensile strength and fatiue strength,Resistant to high-engery radiation.High abrasion and wear resistant.Good electrical insulator even at high voltages,and is characterised mainly by its very good mechanical properties and exceptional dimensional stability even continous operation at high temperatures of up to 250°C.

PEEK performance index
test itemtest standardtest conditionunitsPEEK-1000PEEK-FC1030PEEK-G1030PEEK-C1030
pure resinfilled carbon fiber
(each 10%)
filled 30%
glass fiber
filled 30% carbon fiber
density ISO 1183crystallization g/cm³ 1.3 1.44 1.51 1.4
Bibulous rate (3.2mm thick tensile bar immersion test)
ISO 62-1 24h,23°C % 0.07 0.06 0.04 0.04
% 0.4 0.3 0.4 0.3
tensile strength ISO-527 bend, 23°C MPa 100 140 175 260
elongation at break ISO-527 fracture,23°C % 45 2.2 2.7 1.7
bending strength ISO-178 bend, 23°C MPa 165 190 265 380
flexural modulus ISO-178 23°C GPa 4.1 7.8 11.3 23
compression strength ISO-604 23°C MPa 125 155 250 300
charpy impact
ISO 179/IeA
notched KJ/m² 7 5 8 7
ISO 179/IUno notchKJ/m² 5545
cantilever beam impact test ISO 180/A notched KJ/m² 7.5 5 109
ISO 180/U no totch KJ/m² 6045
shore hardness ISO 868 23°C HD 85 80 8888
melting point ISO 11357 °C 343 343 343343
glass transition tempreture ISO 11357 initial point °C 143 143 143143
specific heat capacity DSC 23°C KJ/kg °C 2.2 1.7 1.71.8
coefficient of thermal expansion ISO 11359 below Tg along the flow direction ppm/K 45 185
overtopTg along the flow direction ppm/K 120 186
distortion temperature ISO 75-f 1.8Mpa °C 152 300 315315
thermal conductivity ISO 22007-4 23°C W/mK 0.29 0.3 0.30.95
dielectrical strength IEC 65713-1 2mm KV/mm 23 25
dielectric constant IEC 65710 23°C,1KHz 3.1 3.2-3.4
23°C,50HZ 3
volume resistivityIEC 60093 23°C, 1V Ω•cm 1016 1016
275°C Ω•cm 109

2. Products Specifications:

Item:Precision PEEK Plastic Injection Molding Electronic Fittings/Parts
Color:Nature, black, white, etc
Material:PEEK,PPS, Nylon, POM
Process:CNC machining

* Strong and stiff plastic
* Outstanding chemical resistance
* Good mechanical properties at elevated temperatures
* Resistant to hot water and steam
* Bearing grade PEEK has excellent wear characteristics
* UL 94 V-0 flammability rating
* Very low smoke and toxic gas emissions when exposed to flame

Typical Applications:
* Semiconductor machinery components
* Aerospace parts
* Seals
* Pump and valve components
* Bearings and bushings (bearing grade PEEK)
* Electrical components
* Medical instrument parts
* Food processing machinery components.

3. Products Pictures:

4. Company Other Products:
Profiles:sheet, rod, tube

Plastic Products & Parts:

Design Considerations for Injection Molded Parts

There are many factors to consider when designing a component for injection molding. These include design factors, materials, overhangs, and process. Understanding these factors will make it easier to choose the right part for the application. In this article, we’ll go over several of the most common design considerations.

Design factors

Injection molded parttTo get the best results from your injection molded parts, you must ensure that they meet certain design factors. These factors can help you achieve consistent parts and reduce cost. These guidelines can also help you to avoid common defects. One of the most common defects is warping, which is caused by the unintended warping of the part as it cools.
When designing injection molded parts, the draft angle is critical. Increasing the draft angle allows the part to emerge cleanly from the mold and reduces stress concentration. This can improve the part’s function and speed up the production process. In addition, it ensures a uniform surface finish. Incorrect draft angles can result in parts that are not functional and can cost you money. If your product team doesn’t pay attention to these design factors, they could end up destroying expensive molds and producing a high number of rejects.
Ribs are another design factor that should be taken into consideration. Rib height should be less than three times the thickness of the part’s wall. This will prevent sink marks and minimize the chances of the ribs sticking inside the mold.


There are many options when it comes to materials for injection molded parts. Choosing the right material will affect how well it performs in your particular application. If you need a large part to be flexible and sturdy, then a plastic with good flow properties will work best. Injection molded plastics come in a variety of different resins. Choose the one that best meets your application’s needs, considering its main functionality and the desired appearance. You may also want to choose a material that is UV resistant, heat resistant, flexible, and food safe.
Polymers that are suitable for injection molding include polycarbonate and polypropylene. These materials are flexible and strong, and can be used to create parts with high-level details. These materials are also lightweight and inexpensive. Despite being flexible, they are not suitable for high-stress applications.
During the molding process, the injected material must be cooled, otherwise it will expand again. This is why you need to keep the temperature of the mould at 80 degrees Celsius or less.


Injection molding is the process of creating plastic parts. The plastic is melted in a mold and then forced to cool. It then solidifies into the desired shape. During the cooling process, the plastic can shrink, so it is important to pack the material tightly in the mold to prevent visible shrinkage. When the mold is completed, it cannot be opened until the required cooling time has passed. This time can be estimated based on the thermodynamic properties of plastic and the maximum wall thickness of the part.
The mold must be precisely designed and tested. The process can be repeated many times, which makes it ideal for mass production. It is also one of the fastest ways to scale production. The more parts a mold can produce, the lower its cost per piece. This is one of the benefits of injection molding.
Injection molding parts are used for many industries, including appliances, electronics, packaging, and medical devices. They can be made to have complicated shapes.


Injection molded parttOverhangs are areas of extra material that surround the surface of an injection molded part. This extra material is typically made of inexpensive material that is edged or glued on the part’s surface. The overhang material can be easily separated from the blank using a simple cutting process.
The amount of material needed for an overhang is dependent on the shape of the part and the amount of surface area. Generally, an overhang is less than 15 percent of the cost of the part. Usually, the material used should be able to fulfill the overhang’s function and differentiate it from the material in the form flachen area.
Overhangs on injection molded parts should be avoided because they may cause the design to become unstable. To avoid this problem, consider designing your part so that the sides and edges are parallel to one another. This will help ensure that the part will be free of undercuts and overhangs.
Overhangs on injection molded parts can be avoided by ensuring that the parts are designed with tolerances in mind. For example, an overhang in an injection molded part can cause a mold to have an overhang that is too small for the machine. This can cause problems in the manufacturing process, and it can result in a costly mold.


Injection molding costs can vary depending on the complexity of the part, the size and the type of plastic. Parts with complex geometries may require additional design work and tooling. Larger parts can also cost more than small ones. The amount of time spent designing and producing them is also important.
To reduce the cost of injection molding, a manufacturer must consider two major factors: tooling and the material used. The plastic used for injection molding has several different properties, which will impact the part price. For instance, plastics with a lot of glass fibers will reduce the amount of time necessary to repair the mold. Another factor to consider is the thermal properties of the material.
The next major factor in the cost of injection molded parts is the material of the injection mold. While most of these molds are made of steel, the type and grade of steel used is important. Injection molds are also required to have nearly wear-free interior cavities. This is necessary to maintain tight tolerances.
Another factor that contributes to the cost of injection molded parts is the cost of bulk material. This material costs money and requires expensive electricity to process. Typically, the more parts you produce, the lower the cost per pound. Storage of bulk material is also a significant expense. Therefore, a quicker cycle time will reduce storage costs.


While manufacturing involves some degree of variation, the variation should be within acceptable limits. This is essential if you want to produce high-quality, dimensionally stable parts. A reliable manufacturing process involves precise control over mold tooling and part design. It also requires repeatability in both quality and production processes.
A reliable injection molding process also focuses on detecting defects early in the production process. Invisible hazards, such as air pockets, mold materials compromised by overheating, and more, can lead to failure. These defects will most likely not be discovered by simple visual inspection and may not come to light until after warranty claims are filed from the field. By finding the defects in the early stages, manufacturers can maximize productivity and reduce costs by minimizing the number of replacement parts needed.
The process of building a custom mould for plastic components is highly skilled. A perfect mould will eliminate potential defects and ensure that the production process is reliable. Traditionally, this process relied on trial and error, which added time and money to the production process.

Design for manufacturability

Injection molded parttWhen designing injection molded parts, it is imperative to keep in mind their manufacturability. Injection molding allows for complex geometries and multiple functions to be combined into a single part. For example, a hinged part can have a single mold that can produce two different halves. This also decreases the overall volume of the part.
Injection molded parts do not typically undergo post-processing. However, the mold itself can be finished to various degrees. If the mold is rough, it can cause friction during the ejection process and require a larger draft angle. Detailed finishing procedures are outlined by the Society of Plastics Industry.
The process of designing injection molds is very exacting. Any errors in the mold design can lead to out-of-spec parts and costly repair. Therefore, the process of Design for Manufacturability (DFM) validation is a key step early in the injection molding process. Fictiv’s DFM feedback process can identify design challenges and provide early feedback to minimize lead times and improve quality.
The surface of an injection molded part can develop sink marks, which occur when the material has not fully solidified when it is ejected from the mold. Parts with thick walls or ribs are more prone to sinking. Another common defect in plastic injection molding is drag marks, which occur when walls scrape against one another during ejection. In addition to sink marks, parts with holes or exposed edges can form knit lines.
China supplier China Factory Manufacturer Precision PEEK Plastic Injection Molding Part Component for Machinery     injection moulding for partsChina supplier China Factory Manufacturer Precision PEEK Plastic Injection Molding Part Component for Machinery     injection moulding for parts
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