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Plastic Injection
Moulding

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ISO 9001:2015

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ISO 14001:2015

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Everything you need. One place.

Our Capabilities

Industrial Engineering

Expertise in materials selection, processing, and design for manufacturability.

Advance Resins

Reliable material handling systems, including storage, drying, and conveying equipment.

Injection Molding

Varying tonnage capacities to accommodate a wide range of part sizes and production volumes

Mold design and fabrication

Skilled engineers and toolmakers utilizing advanced software and equipment for precise, durable, and cost-effective molds

Quality Control

Advanced metrology tools and testing equipment to ensure part quality and customer satisfaction

Automation and robotics

Robotic part handling, and real-time monitoring and control of production process to optimize efficiency

Post-processing

Range of services including trimming, printing, and ultrasonic welding to provide finished parts that meet customer requirements.

Build your brand, leave the product build to us

We provide the best quality Plastic Injection Molding for customers around the world.

A complete end-to-end solution from concept design, dfm, mold flow analysis, mold design, FMEA, multi-cavitation mold fabrication with dedicated process optimization machines and commissioning for mas production of plastic injection molding

Your Reliable Partner

Streamline Your Manufacturing Process

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BUILD YOUR BRAND, LEAVE YOUR PRODUCT BUILD TO US

We pride ourselves in being the most sought after, one-stop solution provider  in the marketplace for box-build plastic molded parts both electrical /electronic goods and static goods

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Design . engineer . manufacture

An Overview of Our Services

Edit Content

Our team of skilled professionals is committed to following this process to deliver exceptional results.

We, at GIH, understand the importance of industrial engineering in delivering effective and efficient solutions that meet the unique needs and requirements of our clients. The process of industrial engineering involves a series of steps, starting from defining the problem or opportunity to continuous improvement. 

Define the problem or opportunity

The first step in the process is to define the problem or opportunity. Our engineers work closely with our clients to identify the key challenges they are facing and develop a deep understanding of their specific needs and requirements.

Develop a Plan

Once defining the problem/opportunity, our team conducts research, analyzes data, and collaborates with stakeholders to identify tailored, innovative solutions using cutting-edge technology.

Design and prototype

The next step is to design and prototype the product or process. Our team creates 3D models, builds physical prototypes, and tests various design iterations to ensure that the product or process meets the required specifications and performance standards.

4. Test and validate

We conduct rigorous testing and validation to ensure that the product or process meets the highest standards of quality and performance. This involves conducting various tests and simulations, as well as gathering feedback from stakeholders.

Implement and monitor

If the product or process meets the required specifications and performance standards, we implement it. Our team trains staff, updates procedures, and installs new equipment to ensure that the implementation is seamless.

Continuous improvement

Finally, the process of industrial engineering is a continuous cycle of improvement. Our team is committed to evaluating new technologies and techniques to incorporate them into our existing processes to ensure that our clients' products and processes remain efficient, effective, and competitive.

GIH has a team of skilled professionals who are dedicated to following the industrial engineering process to deliver exceptional results. We use cutting-edge technology, tools, and techniques to develop innovative solutions that meet the unique needs and requirements of our clients. 

Our commitment to continuous improvement ensures that our clients' products and processes remain at the forefront of the industry.

BUILD YOUR BRAND, LEAVE YOUR PRODUCT BUILD TO US

Contact us Today for a free consultation!

CONTACT US
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Thermoplastics

A family of polymers known for their toughness, strength, and ability to resist wear and abrasion. Nylon is often used in applications that require durability, such as gears, bearings, and automotive parts.

ABS is a thermoplastic polymer that is tough, rigid, and impact-resistant. It is commonly used in automotive parts, toys, and electronic housings.

A transparent thermoplastic that is known for its impact resistance and ability to withstand high temperatures. Polycarbonate is used in a variety of applications, including automotive parts, electronic components, and medical devices.

A thermoplastic that is known for its stiffness, toughness, and low friction. Acetal is often used in applications such as gears, bearings, and electrical components.

A transparent thermoplastic that is known for its clarity, scratch resistance, and weatherability. Acrylic is often used in applications such as automotive lenses, signs, and displays.

A thermoplastic that is known for its toughness, flexibility, and chemical resistance. Polyethylene is often used in applications such as packaging, containers, and toys.

A thermoplastic that is known for its stiffness, toughness, and chemical resistance. Polypropylene is often used in applications such as automotive parts, appliances, and packaging.

 

A thermoplastic that is known for its durability, chemical resistance, and low cost. PVC is often used in applications such as pipes, cable insulation, and vinyl flooring.

 

Engineering Resins

These are materials that can withstand exposure to high temperatures without degrading, losing strength, or melting. High-temperature resins are used in applications such as automotive and aerospace parts, electronics, and appliances.

These are materials that are resistant to fire and combustion. Flame-retardant resins are used in applications such as electrical equipment, construction materials, and transportation components.

These are materials that are highly resistant to degradation and damage from exposure to harsh chemicals, solvents, and other corrosive substances. These materials are used in a variety of applications, including chemical processing, medical devices, and automotive parts.

Bioplastics

PLA is a biodegradable thermoplastic derived from renewable resources such as corn starch, cassava roots, or sugarcane. It is a polyester that has good strength and stiffness properties and is commonly used in packaging, disposable tableware, and 3D printing.

PHAs are a family of biodegradable polyesters produced by microorganisms such as bacteria. PHAs have properties similar to conventional thermoplastics and can be processed using standard injection molding techniques. They are used in applications such as packaging, food service items, and medical devices.

PBS is a biodegradable polymer made from succinic acid and 1,4-butanediol. It has good mechanical properties and can be used in a variety of applications including packaging, textiles, and automotive parts.

 

Composites

FRPs are a type of composite material that consist of a polymer matrix reinforced with fibers such as glass, carbon, or aramid. FRPs are strong, lightweight, and have high stiffness, making them suitable for applications in aerospace, automotive, and construction industries.

A composite material consisting of glass fibers and a polymer matrix. GFRP has good strength and stiffness properties and is commonly used in construction, automotive, and marine applications.

High-strength composite material consisting of carbon fibers and a polymer matrix. CFRP has a high strength-to-weight ratio and is commonly used in aerospace, automotive, and sporting goods applications.

Natural fiber composites are made from natural fibers such as wood, flax, or hemp, and a polymer resin. They are lightweight and have good strength and stiffness properties. They are commonly used in automotive, construction, and consumer goods applications.

These are just a few examples of the many types of resins that are suitable for plastic injection molding. The choice of material will depend on the specific requirements of the application, such as mechanical properties, chemical resistance, and cost.

The suitability of a material for injection molding depends on various factors such as its melting point, viscosity, and flow characteristics. Each material may require different injection molding parameters such as temperature, pressure, and cooling time to achieve the desired properties.

Therefore, it is essential to consult with a material expert or a plastic injection molding company to determine the suitability of a specific material for injection molding.

BUILD YOUR BRAND, LEAVE YOUR PRODUCT BUILD TO US

Contact us Today for a free consultation!

CONTACT US

Plastic Resins

Plastic resins are the raw materials used in injection molding, we use best plastic resin for our production

Mold Material

The mold is a critical component in injection molding and is usually made of steel or aluminum. Steel molds are more durable and can withstand high temperatures and pressures, making them ideal for high-volume production

Mold Release Agents

Mold release agents are used to prevent the plastic part from sticking to the mold surface.

Colorant

Colorants are added to the plastic resin to give the finished product a desired color

Addictives

used to improve the properties of the plastic material. Common additives include fillers, plasticizers, and stabilizers. Fillers can improve the strength and stiffness of the plastic, while plasticizers can make it more flexible

Lubricants

Lubricants are used to reduce friction between the plastic and the mold surface, which can help to prevent defects in the finished product.

Coolants

Coolants are used to remove heat from the mold, which is necessary to prevent warping or other defects in the finished product

Solvents

used to clean the mold after each cycle, removing any residual plastic or mold release agent
Edit Content

Plastic Injection Molding Process

Designing The Mold

  • 3D CAD model of the part is created, and a mold design is developed that includes the mold cavity, gating system, and ejection system.
  • The mold design considers factors such as material flow, cooling time, and part ejection.
  • The design is finalized and sent to the mold manufacturer for production.

    • 1st Step

    Material Selection

  • The plastic material is selected based on the desired properties of the finished part and factors such as cost, availability, and compatibility with the molding process.
  • Material is typically in pellet form and is fed into the injection molding machine's hopper.
  • Melted material injected into the mold cavity to form the part.

    • 2nd Step

    Injection Molding

  • Mounted mold injected into molding machine, and the machine is set up with the appropriate temperature and pressure settings.
  • Melted plastic is injected into the mold cavity at high pressure, filling the cavity and forming the part.
  • The mold is held closed under pressure until the plastic has solidified.

    • 3rd Step

    Cooling and Ejection

  • The mold is opened, and the part is ejected from the mold.
  • Cooled down to its final shape and temperature, which can vary depending on the size and complexity of the part and the material being used.
  • Finished part may require additional finishing processes such as trimming, polishing, or painting.

    • 4th Step

    Quality Control:

  • The finished parts are inspected for defects, such as warping, voids, or sink marks.
  • The parts are also checked for dimensional accuracy and other critical specifications.
  • Any defects are addressed before the parts are shipped to the customer.

    • 5th Step

    BUILD YOUR BRAND, LEAVE YOUR PRODUCT BUILD TO US

    Contact us Today for a free consultation!

    CONTACT US
    Edit Content

    Plastic Injection Molding

    we are committed to ensuring the highest level of quality control to provide our valued customers with products and services that exceed their expectations. From stringent quality checks to meticulous attention to detail, we go above and beyond to ensure that every item we offer is of the highest quality.

    Experience seamless precision and unmatched quality with our advanced plastic injection molding technology - click here to discover how we can bring your product ideas to life!

    Read More

    BUILD YOUR BRAND, LEAVE YOUR PRODUCT BUILD TO US

    Contact us Today for a free consultation!

    CONTACT US
    Edit Content

    Our Quality Control

    we are committed to ensuring the highest level of quality control to provide our valued customers with products and services that exceed their expectations. From stringent quality checks to meticulous attention to detail, we go above and beyond to ensure that every item we offer is of the highest quality.

    Our rigorous manufacturing quality control processes ensure that every product meets our high standards.

    Read More

    BUILD YOUR BRAND, LEAVE YOUR PRODUCT BUILD TO US

    Contact us Today for a free consultation!

    CONTACT US
    Edit Content

    Bring Innovation to Your Company

    At our injection molding facility, we understand the importance of staying at the forefront of technological advancements. To this end, we have implemented robotics and automation in our plant to streamline production processes and enhance efficiency.

    ERP Systems for Production Floor

    Challenge

    The manual systems in place for production processes were causing delays and inefficient use of resources.

    Solution

    We implemented an enterprise resource planning (ERP) system for the production floor. The system automated data collection and analysis, enabling real-time monitoring of production processes and resource utilization. It also streamlined communication between departments, enabling better decision-making.

    Result

    The ERP system resulted in a 20% increase in production efficiency and a 8% reduction in operational costs.

    Pick and Place Robots from Machines on to Conveyor Belts

    Challenge

    The manual handling of products from injection molding machines onto conveyor belts was relatively slow and we needed to increase our output efficiency fast.

    Solution

    We implemented pick and place robots to automate the handling of products from injection molding machines onto conveyor belts. The robots used a combination of sensors and artificial intelligence to pick and place the products with precision and accuracy.

    Result

    The pick and place robots reduced the risk of product damage, resulting in a 7% reduction in waste and a 5% increase in production efficiency.

    Oil and Water-Based Mold Temperature Controllers (MTCs)

    Challenge

    Controlling mold temperature is critical to ensuring the quality of plastic components produced through injection molding. However, the manual control of mold temperature was causing variations in the quality of the final product.

    Solution

    We implemented oil and water-based mold temperature controllers (MTCs) to automate the control of mold temperature. The MTCs used a combination of sensors and controllers to maintain a consistent temperature throughout the molding process.

    Result

    The use of oil and water-based MTCs resulted in a significant improvement in the quality of plastic components produced through injection molding. The automated control of mold temperature reduced variations in the quality of the final product, resulting in a 35% reduction in waste and a 20% increase in production efficiency.

    Dehumidifying Dryers and Auto Material Loaders

    Challenge

    The quality of plastic components was being affected due to the moisture present in the raw materials, and the manual handling of materials was causing inefficiencies and delays in production.

    Solution

    We installed dehumidifying dryers and auto material loaders to maintain the quality of raw materials and automate the handling of materials from storage to the injection molding machines. The dryers and loaders were integrated with the production processes, enabling real-time monitoring and control.

    Result

    The dehumidifying dryers and auto material loaders reduced material waste by 10%, increased production efficiency by 5%, and improved product quality by ensuring the moisture content of raw materials was within acceptable limits.

    BUILD YOUR BRAND, LEAVE YOUR PRODUCT BUILD TO US

    Contact us Today for a free consultation!

    CONTACT US
    Edit Content

    Post
    Processing

    Tampo Printing and Ultrasonic Welding are advanced manufacturing technologies that can greatly benefit businesses by offering precise and efficient production processes.

    Integrating these advanced technologies into your manufacturing process can significantly enhance product quality, increase production efficiency, and reduce costs, leading to a competitive advantage and increased customer satisfaction.

    Upgrade your manufacturing process with our advanced technologies.

    Read More
    Edit Content

    Our team of skilled professionals is committed to following this process to deliver exceptional results.

    We, at GIH, understand the importance of industrial engineering in delivering effective and efficient solutions that meet the unique needs and requirements of our clients. The process of industrial engineering involves a series of steps, starting from defining the problem or opportunity to continuous improvement. 

    Define the problem or opportunity

    The first step in the process is to define the problem or opportunity. Our engineers work closely with our clients to identify the key challenges they are facing and develop a deep understanding of their specific needs and requirements.

    Develop a Plan

    Once defining the problem/opportunity, our team conducts research, analyzes data, and collaborates with stakeholders to identify tailored, innovative solutions using cutting-edge technology.

    Design and prototype

    The next step is to design and prototype the product or process. Our team creates 3D models, builds physical prototypes, and tests various design iterations to ensure that the product or process meets the required specifications and performance standards.

    4. Test and validate

    We conduct rigorous testing and validation to ensure that the product or process meets the highest standards of quality and performance. This involves conducting various tests and simulations, as well as gathering feedback from stakeholders.

    Implement and monitor

    If the product or process meets the required specifications and performance standards, we implement it. Our team trains staff, updates procedures, and installs new equipment to ensure that the implementation is seamless.

    Continuous improvement

    Finally, the process of industrial engineering is a continuous cycle of improvement. Our team is committed to evaluating new technologies and techniques to incorporate them into our existing processes to ensure that our clients' products and processes remain efficient, effective, and competitive.

    GIH has a team of skilled professionals who are dedicated to following the industrial engineering process to deliver exceptional results. We use cutting-edge technology, tools, and techniques to develop innovative solutions that meet the unique needs and requirements of our clients. 

    Our commitment to continuous improvement ensures that our clients' products and processes remain at the forefront of the industry.

     

    BUILD YOUR BRAND, LEAVE YOUR PRODUCT BUILD TO US

    Contact us Today for a free consultation!

    CONTACT US
    Edit Content
    Edit Content

    A family of polymers known for their toughness, strength, and ability to resist wear and abrasion. Nylon is often used in applications that require durability, such as gears, bearings, and automotive parts.

    ABS is a thermoplastic polymer that is tough, rigid, and impact-resistant. It is commonly used in automotive parts, toys, and electronic housings.

    A transparent thermoplastic that is known for its impact resistance and ability to withstand high temperatures. Polycarbonate is used in a variety of applications, including automotive parts, electronic components, and medical devices.

    A thermoplastic that is known for its stiffness, toughness, and low friction. Acetal is often used in applications such as gears, bearings, and electrical components.

    A transparent thermoplastic that is known for its clarity, scratch resistance, and weatherability. Acrylic is often used in applications such as automotive lenses, signs, and displays.

    A thermoplastic that is known for its toughness, flexibility, and chemical resistance. Polyethylene is often used in applications such as packaging, containers, and toys.

    A thermoplastic that is known for its stiffness, toughness, and chemical resistance. Polypropylene is often used in applications such as automotive parts, appliances, and packaging.

     

    A thermoplastic that is known for its durability, chemical resistance, and low cost. PVC is often used in applications such as pipes, cable insulation, and vinyl flooring.

     

    Edit Content

    These are materials that can withstand exposure to high temperatures without degrading, losing strength, or melting. High-temperature resins are used in applications such as automotive and aerospace parts, electronics, and appliances.

    These are materials that are resistant to fire and combustion. Flame-retardant resins are used in applications such as electrical equipment, construction materials, and transportation components.

    These are materials that are highly resistant to degradation and damage from exposure to harsh chemicals, solvents, and other corrosive substances. These materials are used in a variety of applications, including chemical processing, medical devices, and automotive parts.

    Edit Content

    PLA is a biodegradable thermoplastic derived from renewable resources such as corn starch, cassava roots, or sugarcane. It is a polyester that has good strength and stiffness properties and is commonly used in packaging, disposable tableware, and 3D printing.

    PHAs are a family of biodegradable polyesters produced by microorganisms such as bacteria. PHAs have properties similar to conventional thermoplastics and can be processed using standard injection molding techniques. They are used in applications such as packaging, food service items, and medical devices.

    PBS is a biodegradable polymer made from succinic acid and 1,4-butanediol. It has good mechanical properties and can be used in a variety of applications including packaging, textiles, and automotive parts.

     

    Edit Content

    FRPs are a type of composite material that consist of a polymer matrix reinforced with fibers such as glass, carbon, or aramid. FRPs are strong, lightweight, and have high stiffness, making them suitable for applications in aerospace, automotive, and construction industries.

    A composite material consisting of glass fibers and a polymer matrix. GFRP has good strength and stiffness properties and is commonly used in construction, automotive, and marine applications.

    High-strength composite material consisting of carbon fibers and a polymer matrix. CFRP has a high strength-to-weight ratio and is commonly used in aerospace, automotive, and sporting goods applications.

    Natural fiber composites are made from natural fibers such as wood, flax, or hemp, and a polymer resin. They are lightweight and have good strength and stiffness properties. They are commonly used in automotive, construction, and consumer goods applications.

    These are just a few examples of the many types of resins that are suitable for plastic injection molding. The choice of material will depend on the specific requirements of the application, such as mechanical properties, chemical resistance, and cost.

    The suitability of a material for injection molding depends on various factors such as its melting point, viscosity, and flow characteristics. Each material may require different injection molding parameters such as temperature, pressure, and cooling time to achieve the desired properties.

    Therefore, it is essential to consult with a material expert or a plastic injection molding company to determine the suitability of a specific material for injection molding.

    BUILD YOUR BRAND, LEAVE YOUR PRODUCT BUILD TO US

    Contact us Today for a free consultation!

    CONTACT US

    Critical Materials Used

    Plastic Resins

    Plastic resins are the raw materials used in injection molding, we use best plastic resin for our production

    Mold Material

    The mold is a critical component in injection molding and is usually made of steel or aluminum. Steel molds are more durable and can withstand high temperatures and pressures, making them ideal for high-volume production

    Mold Release Agents

    Mold release agents are used to prevent the plastic part from sticking to the mold surface.

    Colorant

    Colorants are added to the plastic resin to give the finished product a desired color

    Addictives

    used to improve the properties of the plastic material. Common additives include fillers, plasticizers, and stabilizers. Fillers can improve the strength and stiffness of the plastic, while plasticizers can make it more flexible

    Lubricants

    Lubricants are used to reduce friction between the plastic and the mold surface, which can help to prevent defects in the finished product.

    Coolants

    Coolants are used to remove heat from the mold, which is necessary to prevent warping or other defects in the finished product

    Solvents

    used to clean the mold after each cycle, removing any residual plastic or mold release agent
    Edit Content

    Plastic Injection Molding Process

    Designing The Mold

  • 3D CAD model of the part is created, and a mold design is developed that includes the mold cavity, gating system, and ejection system.
  • The mold design considers factors such as material flow, cooling time, and part ejection.
  • The design is finalized and sent to the mold manufacturer for production.

    • 1st Step

    Material Selection

  • The plastic material is selected based on the desired properties of the finished part and factors such as cost, availability, and compatibility with the molding process.
  • Material is typically in pellet form and is fed into the injection molding machine's hopper.
  • Melted material injected into the mold cavity to form the part.

    • 2nd Step

    Injection Molding

  • Mounted mold injected into molding machine, and the machine is set up with the appropriate temperature and pressure settings.
  • Melted plastic is injected into the mold cavity at high pressure, filling the cavity and forming the part.
  • The mold is held closed under pressure until the plastic has solidified.

    • 3rd Step

    Cooling and Ejection

  • The mold is opened, and the part is ejected from the mold.
  • Cooled down to its final shape and temperature, which can vary depending on the size and complexity of the part and the material being used.
  • Finished part may require additional finishing processes such as trimming, polishing, or painting.

    • 4th Step

    Quality Control:

  • The finished parts are inspected for defects, such as warping, voids, or sink marks.
  • The parts are also checked for dimensional accuracy and other critical specifications.
  • Any defects are addressed before the parts are shipped to the customer.

    • 5th Step

    Edit Content

    Plastic Injection Molding

    we are committed to ensuring the highest level of quality control to provide our valued customers with products and services that exceed their expectations. From stringent quality checks to meticulous attention to detail, we go above and beyond to ensure that every item we offer is of the highest quality.

    Experience seamless precision and unmatched quality with our advanced plastic injection molding technology - click here to discover how we can bring your product ideas to life!

    Read More
    Edit Content

    Our Quality Control

    we are committed to ensuring the highest level of quality control to provide our valued customers with products and services that exceed their expectations. From stringent quality checks to meticulous attention to detail, we go above and beyond to ensure that every item we offer is of the highest quality.

    Our rigorous manufacturing quality control processes ensure that every product meets our high standards.

    Read More
    Edit Content

    Bring Innovation to Your Company

    At our injection molding facility, we understand the importance of staying at the forefront of technological advancements. To this end, we have implemented robotics and automation in our plant to streamline production processes and enhance efficiency.

    ERP Systems for Production Floor

    Challenge

    The manual systems in place for production processes were causing delays and inefficient use of resources.

    Solution

    We implemented an enterprise resource planning (ERP) system for the production floor. The system automated data collection and analysis, enabling real-time monitoring of production processes and resource utilization. It also streamlined communication between departments, enabling better decision-making.

    Result

    The ERP system resulted in a 20% increase in production efficiency and a 8% reduction in operational costs.

    Pick and Place Robots from Machines on to Conveyor Belts

    Challenge

    The manual handling of products from injection molding machines onto conveyor belts was relatively slow and we needed to increase our output efficiency fast.

    Solution

    We implemented pick and place robots to automate the handling of products from injection molding machines onto conveyor belts. The robots used a combination of sensors and artificial intelligence to pick and place the products with precision and accuracy.

    Result

    The pick and place robots reduced the risk of product damage, resulting in a 7% reduction in waste and a 5% increase in production efficiency.

    Oil and Water-Based Mold Temperature Controllers (MTCs)

    Challenge

    Controlling mold temperature is critical to ensuring the quality of plastic components produced through injection molding. However, the manual control of mold temperature was causing variations in the quality of the final product.

    Solution

    We implemented oil and water-based mold temperature controllers (MTCs) to automate the control of mold temperature. The MTCs used a combination of sensors and controllers to maintain a consistent temperature throughout the molding process.

    Result

    The use of oil and water-based MTCs resulted in a significant improvement in the quality of plastic components produced through injection molding. The automated control of mold temperature reduced variations in the quality of the final product, resulting in a 35% reduction in waste and a 20% increase in production efficiency.

    Dehumidifying Dryers and Auto Material Loaders

    Challenge

    The quality of plastic components was being affected due to the moisture present in the raw materials, and the manual handling of materials was causing inefficiencies and delays in production.

    Solution

    We installed dehumidifying dryers and auto material loaders to maintain the quality of raw materials and automate the handling of materials from storage to the injection molding machines. The dryers and loaders were integrated with the production processes, enabling real-time monitoring and control.

    Result

    The dehumidifying dryers and auto material loaders reduced material waste by 10%, increased production efficiency by 5%, and improved product quality by ensuring the moisture content of raw materials was within acceptable limits.

    Edit Content

    Post
    Processing

    Tampo Printing and Ultrasonic Welding are advanced manufacturing technologies that can greatly benefit businesses by offering precise and efficient production processes.

    Integrating these advanced technologies into your manufacturing process can significantly enhance product quality, increase production efficiency, and reduce costs, leading to a competitive advantage and increased customer satisfaction.

    Upgrade your manufacturing process with our advanced technologies.

    Read More

    BUILD YOUR BRAND, LEAVE YOUR PRODUCT BUILD TO US

    Contact us Today for a free consultation!

    CONTACT US

    Frequently Asked Question

    Plastic injection molding is a highly versatile and efficient manufacturing process that involves melting plastic resin and injecting it into a mold cavity to produce a finished part. Our company has years of experience in the industry and can provide high-quality injection molding services to meet your needs.

    We offer a wide range of plastic resins to suit your specific requirements. From ABS and polycarbonate to nylon and polypropylene, our expert team can help you choose the best material for your project.

    Our experienced team is committed to delivering your project on time and on budget. Lead times will depend on factors such as the complexity of the part and the availability of tooling, but we work closely with our clients to ensure that their projects are completed in a timely manner.

    Our state-of-the-art injection molding machines can produce parts of various sizes, from small, intricate components to large, complex parts. We have the capacity and expertise to deliver your project, no matter the size or complexity.

    We understand that every project is unique, and we can work with you to find the best solution to meet your needs. Our company has the flexibility to produce small, medium, and large quantities of parts to suit your specific requirements.

    We strive to provide cost-effective solutions for our clients and offer competitive pricing for our injection molding services. The cost of your project will depend on various factors, including the complexity of the part, the quantity needed, and the choice of plastic resin. We will work closely with you to develop a pricing structure that meets your budget.

    Quality control is an essential part of our injection molding process. We use state-of-the-art automated inspection equipment, such as CMM machines and optical comparators, to ensure that the finished parts meet the required specifications. Our team is committed to delivering high-quality products that exceed your expectations.

    Yes, injection molding is an excellent process for producing parts with complex geometries. Our team has the expertise to design and produce specialized tooling that can help to produce parts with intricate shapes and features.

    While 3D printing is a process that involves building up layers of material to produce a finished part, injection molding involves melting plastic resin and injecting it into a mold cavity to produce a finished part. 3D printing is generally used for producing small quantities of parts or prototypes, while injection molding is used for high-volume production.

    Our company is committed to sustainability, and we have implemented various measures to reduce our environmental impact. We use sustainable materials, such as biodegradable plastics, and implement recycling programs to reduce waste. We also implement energy-efficient practices and use renewable energy sources to power our operations.

    The suitability of a material for injection molding depends on several factors, such as its melting point, viscosity, and flow characteristics. Each material may require different injection molding parameters, such as temperature, pressure, and cooling time, to achieve the desired properties. Therefore, it is recommended to consult with a material expert or a plastic injection molding company to determine the suitability of a specific material for injection molding. At our company, we have material experts who can guide you in selecting the best material for your product and provide you with the necessary injection molding parameters to achieve the desired properties.

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