Rubber Molding Industry Information

Rubber Molding

Today, numerous commercial products utilize molded rubber products as important assembly components. From custom mold making and industrial roller manufacturing machinery to gaskets, grommets, seals, and parts in medical equipment, housewares, consumer appliances and more, rubber molding contributes to diverse products in the marketplace today. You’ll discover a great selection of rubber molding manufacturers listed above. Use this website to locate the fine custom products you require for your enterprise. Rubber molding is the process by which raw rubber is melted and formed in a mold. It is the method of choice in the creation of many different kinds of complex rubber products.

Quick links to Rubber Molding Information

  • The History of Rubber Molding
  • The Advantages of Rubber Molding
  • The Rubber Molding Materials Process
  • Rubber Molding Types
  • Molded Rubber Applications
  • A Closer Look at Rubber Molding
  • Rubber Molding Machinery
  • Why Choose Custom Rubber Molding?
  • Selecting a Rubber Molding Manufacturer
  • Variations of Rubber Creation
  • Rubber Molding Terms

The History of Rubber Molding

Some South American tribal peoples have reportedly utilized the sap from rubber trees for thousands of years to make household items. However, industrial rubber really did not become significant as a commercial product until the late Nineteenth Century. The development of vulcanization allowed rubber to withstand extensive processing without degrading.

In 1823, a Scottish chemist named Charles Macintosh discovered he could apply rubber to cloth using a coal-tar byproduct to cement regular cloth to cloth with a rubbery surface. Interest in rubber products grew in Europe and the USA during the Victorian Era. However, early rubber products displayed some serious disadvantages; the rubber became gummy during hot weather. It frequently deteriorated and grew malodorous. Rubber erasers and shoe soles did gain some popularity despite these drawbacks.

In 1839, an American named Charles Goodyear discovered the process of vulcanizing. Adding sulfur to rubber enhanced its durability by stabilizing polymers in the latex. Although he received a patent in 1844, his invention did not receive widespread commercial use during his lifetime. Vulcanization grew widespread only with the development of rubber bicycle tires and automobile tires after 1889. During the late 1800s, entrepreneurs established rubber plantations in many tropical regions and the demand for rubber in international commerce increased. By the early 1900s, a flourishing global rubber industry had arisen.

Despite its utility, rubber molding achieved popularity only decades later. Advances in chemistry led to an interest in the development of synthesized plastics during the second half of the 19th Century. Inventors John and Isaiah Hyatt, brothers, reportedly patented the first injection molding machine in 1872. They eventually used this invention to create both rubber and plastic products. Subsequent inventors continued to improve rubber molding technology throughout the late 1800s and the Twentieth Century.

The development of plastics contributed significantly to improvements in injection molding technology. Liquid silicone molding capabilities increased significantly during the 1970s, following James Watson Hendry’s invention of a gas-powered process for injection molding. During subsequent decades, the use of automation increased significantly. Today, computers assist many rubber injection molding production efforts. Companies supplying custom molding services have increased as many firms have begun specializing in specific types of rubber molding.

The Advantages of Rubber Molding

Molding offers important advantages over other types of rubber product production processes in certain situations. While this process may lack the production speed of rubber extrusion, for instance, it does permit the generation of a wide variety of complex parts. Additionally, molding offers versatility. It utilizes many different formulations of rubber-based raw materials, allowing the generation of products with different desired properties, such as durability or high heat resistance. Modern rubber molding facilities can mass produce custom products quickly and efficiently. A customer utilizing a proprietary rubber compound for a brand can create prototype products for marketing purposes or commission large production runs, for example.

The Rubber Molding Materials Process

Manufacturers today use a variety of processes for molding natural and synthetic rubber. These processes include:

Injection Molding
Predominates today in the commercial marketplace. It typically supplies inexpensive plastic components during mass production runs. A rubber injection molding manufacturer creates a production line to transform solid rubber or synthetic rubber stock into molten material injected into a terminal mold cavity. Manufacturers usually automate this process through the use of fast-paced computerized machinery. The combination of heat and pressure assist the manufacturer in achieving uniform mold filling. During cooling, a rubber product solidifies into a desired shape. The mold then ejects the plastic work piece, which may require additional finishing before use in an assembly (or not).
Compression Molding
This process has achieved popularity as a way to create low tolerance rubber or synthetic rubber parts. The manufacturer performs the stock into a desired shape and weight and then inserts it into a mold cavity. The closing of the heavy compression mold helps squeeze the preformed material into a desired shape. The manufacturer heats molds to designated temperatures and allows them to remain closed for specified periods of time to optimize the production of final products.
Liquid Injection Molding
Closely resembles the conventional rubber injection molding process. However, manufacturers utilize liquid stock such as liquid silicone rubber as the starting raw material. The machinery which accomplishes this process usually includes some form of metered pump to help regulate and control the flow of silicone. The manufacturer mixes the liquid silicone with any other applicable constituents after the initial metered discharge. Then a nozzle injects the mixture into a mold. After securing the mold tightly with clamps, the manufacturer applies a designated amount of heat and pressure to create a product. Liquid injection molding may shorten the production process, since the manufacturer does not need to transform solid stock into a liquid state to initiate molding. Products generated in this way also require very little finishing.
Transfer Molding
Allows manufacturers to produce both rubber items bonded to metal surfaces, and precision molded rubber parts. As with compression molding, the manufacturer uses preformed rubber in a designated weight. However, instead of placing this material into an open mold, the manufacturer inserts it into a cavity located above the mold called a “pot” and then applies a heavy mechanical part known as a “ram” to force the preform to transfer into the mold through a runner and gate system as it melts upon the application of heat and pressure. The ram remains in place over the mold for a specified period of time.

Rubber Molding Types

Blow Molding
A less-common process of placing a hollow tube between the two halves of a blow mold. The blow mold then closes, pinching off the bottom half of the tube, and air is injected into the top, forcing the material outwards to the walls of the blow mold.
Foam Rubber
Rubber that was manufactured with the addition of a foaming agent in order to create a flexible, air-filled substance.
Liquid Silicone Rubber
The liquid form of a synthetic, two-component, elastomeric polymer that is made from silicone elastomers.
Rubber Baseboard
A molded rubber product used to cover the joint that is formed when a wall meets the floor.
Rubber Diaphragm
Flexible seals that are resistant to a variety of media at different pressures.
Rubber Grommets
Rubber rings inserted into a hole in sheet metal to protect cords or electrical wires from abrasion.
Rubber Seals
Used to prevent leakage at joints.
Rubber Sheets
Flat pieces of rubber used for a variety of purposes.
Rubber Tubing
Refers to long, hollow cylinders used to transport liquids and gases.
Rubber Washers
Primarily used to support the weight of a threaded fastener, but are also used in taps or valves to control the flow of liquids or gases.
Rubber Molders
An operation where rubber components are shaped into useful products.
Viton Rubber Molding
A specialized synthetic rubber that is combined with a fluoropolymer elastomer. This combination makes viton rubber particularly durable in applications where it will be exposed to aggressive chemicals.

Molded Rubber Applications

The ability of manufacturers to shape molded rubber into complex forms enhances the usefulness of flexible rubber and synthetic-rubber parts. It enables engineers to obtain useful seals and cushioning components. In mechanical assemblies, parts made from rubber sometimes help reduce the impact of vibration. They may dampen noise in some products, for instance.

The development of different types of man-made rubber-based products has further increased the demand for rubber molding. Synthetic materials such as neoprene, silicone, EPDM (ethylene propylene diene monomer M-class rubber), and other elastomers modify the properties of rubber, enabling rubber manufacturers to produce a variety of items for specific purposes. Additionally, specialized processes permit the affixation of rubber or synthetic rubber layers to some metal parts.

Most industries use multiple rubber molding products. This technology assists manufacturers in the agricultural, industrial, electronic, transportation, defense, construction, consumer goods, and biotech sectors. For example, molded rubber frequently permits designers to create useful models for new or custom products. It may expedite the creation of samples for market testing purposes. Some companies specialize in generating rapid custom mold prototypes for clients, for instance.

Rubber custom molding also enables manufacturers to generate unique components for assemblies. The use of a mold cavity facilitates the production of richly detailed, complex parts. Today, manufacturers obtain a wide range of competitively priced rubber parts through this process. From the custom molding of grommets and gaskets to the generation of distinctive flexible rubber edge trim, custom rubber molding helps promote brand development and the creation of original equipment manufacturer parts.

A Closer Look at Rubber Molding

Today rubber molding frequently involves the use of synthetic as well as natural rubbers. Some common raw materials used in rubber molding include:

Natural Rubber Latex
Today some manufacturers still generate natural rubber latex products using natural rubber latex components. Agricultural workers draw a milky latex sap from the tropical hevea brasiliensis tree or from certain trees of the genus Ficus. They cut into the tree and allow the sap to flow in small quantities into attached containers. Producers then mix the latex gathered from several trees with formic acid, which causes the sap to coagulate into a solid sheet. After initial processing, this organic uncured rubber substance provides a raw material for use in natural rubber latex molding.
Typically, instead of creating natural rubber latex products directly, rubber producers send natural latex rubber to factories to undergo vulcanization prior to export. This step causes the rubber to harden further, allowing easier shipment. Manufacturers then create vulcanized rubber products.
One of the earliest synthetic rubbers, neoprene results from research performed by the DuPont Corporation during the 1930s. This general-purpose chloroprene polymer still forms a component of many commercial products today. Rubber molding manufacturers employ it to form gaskets, liners and a variety of houseware and gardening items. Some widely-used chemicals eventually break down neoprene, including iodine, turpentine and acetic acid, so it enjoys limited utility for industrial applications.
EPDM (Ethylene-Propylene-Diene Monomer)
This polymer has obtained widespread use in the construction and automotive industries. It frequently contributes to roofing materials in commercial buildings, for instance. Automakers rely heavily upon molded EPDM parts in electrical gaskets and in trunk, door and window seals. It serves as the constituent material for many engine cooling system hoses, also.
Silicone Rubber
Silicone, a man-made rubber, consists of the element silicon, as well as oxygen, carbon and hydrogen. Manufacturers who use this polymer can make this mix into either a liquid or a solid. It offers resistance to high temperatures, and reportedly remains stable at temperatures of up to 446 degrees Fahrenheit, making it a very useful product in molds during some types of metal casting. Additionally, manufacturers can sanitize silicone rubber items readily. Silicone has also found widespread utility in components in the medical, biotech and food processing machinery industries.

Rubber Molding Machinery

Today an impressive variety of rubber molding machinery creates products in many industries. As automation has increased, the cost of some sophisticated high-volume machines has also risen. Today, an injection molding machine often represents a significant investment.

The availability of custom molding services has permitted enterprises of many sizes to enter the rubber products manufacturing marketplace. The specific raw materials, equipment, rubber injection methods and tools required may vary widely from one production setting to another, depending upon the type of products created by manufacturers.

Why Choose Custom Rubber Molding?

Custom rubber molding is the ability to create a design and have it manufactured on the spot by a rubber molding manufacturer. Customized designs are better for certain companies that require unique designs for their needs and new products. There are many other ways to create custom products, but not all methods are best for all uses.

Rubber molding is beneficial because it offers a variety of services to the user. For injection molding, the costs of custom rubber molding are lower than some other forms of rubber manufacturing. In large volume runs, injection rubber molding is the ideal choice.

When using custom rubber molding, the run time of the process is reduced. This will save both time and money for large volume rubber runs. Machines using the latest molding technology have a variety of automation capabilities that reduces the cost of custom molding even lower. Using a material like liquid silicone rubber creates precision, tight tolerance parts. It is possible to create products with a variety of finishes and textures when using rubber molding.

Some of the industries that can benefit from custom molding include:

Custom devices, blood analysis machines, surgical instruments.
Electrical connector inserts, EMI shielding, high performance seals and gaskets.
Cable boots, vibration isolators, power supply gaskets, keypads.
Oil and gas components, fluid pumps, customized buttons and vibration absorbers.

Selecting a Rubber Molding Manufacturer

The IQS Directory website supplies contact information for a variety of excellent rubber molding manufacturing companies. Many companies specialize in specific types of molding processes. Use this helpful directory to assist your company in locating the best manufacturing firm to meet your needs!

Variations of Rubber Creation

Instead of generating rubber components through molding processes, sometimes manufacturers employ extruding or calendaring:

Rubber Extrusions
The process of rubber extrusions helps form rubber tubing or strips with the assistance of dies. Machines may force a rubber or plastic through cross sectional dies to create specific shapes for products such as residential baseboard molding or curtain rods, for example.
Rubber Calendaring
During this manufacturing process, a manufacturer uses a series of rollers to press and flatten raw materials, frequently applying them over other materials, such as textiles. This process can create fabrics that include plastic or rubber components. It may also produce rubberized coatings, films, and sheets.

Rubber Molding Terms

Abrasion Resistance
A rubber compound’s capability to withstand mechanically caused deterioration.
Accelerated Life Test
A test made to replicate in a short period of time the breakdown resulting from normal working conditions.
A substance that increases the speed of vulcanization when used in small quantities in conjunction with vulcanizing agents.
A compound used to increase the effectiveness of an accelerator, small amounts at a time.
Tendency of rubber to cling or bond to any surface it contacts.
The continuance of vulcanization, even after the energy source has been taken away.
Air Checks
Depressions and marks on the surface of rubber, caused by air trapped during the molding process.
Uses steam under pressure to vulcanize rubber products.
A defect in the molding process, where the rubber near the parting line sinks below the surface and the parting line ends up ragged and torn.
The result of a mixing operation.
Rubber compound that fills a mold.
A discoloration of rubber, caused by a liquid or solid migrating towards the surface.
Breakout Friction
The necessary force to start the sliding between a rubber seal and its mating surface.
The development of a powdery residue on a rubber surface as a result of surface breakdown.
Small cracks on the surface of rubber, usually from environmental damage.
Compression Set
The permanent deformation of rubber after removing the compression.
Conducting Rubber
Rubber that is able to conduct electricity.
A chemical bond between polymer chains.
Cure Date
The date of completion of the molding process for a rubber product.
Any of a variety of processes for waste edge removal from molded rubber parts.
The application of force used to evenly disperse various compounds through rubber.
An instrument that measures the hardness of rubber.
Applying powder to rubber to prevent adhesion to something else.
Dynamic Seal
A seal necessary for the prevention of leaks beyond parts that are in relative motion.
A characteristic of rubber, describing its tendency to return to its initial shape after warping.
Extension of rubber when exposed to stress.
A machine that forces rubber through a hole that shapes it into the finished product.
Fatigue Breakdown
The wearing out of elastomers after repeated deformations.
Flexural Strength
The flexing capability of a material with no permanent deformation or breakage.
Capability of uncured rubber to move in the mold and runner system in the molding procedure.
High Consistency Rubber (HCR)
Rubber processed on a rubber mill that has a much greater viscosity than liquid silicone rubber.
The process of mechanical energy changing to heat in rubber under strain.
A material that rubber is chemically or physically bonded to during the molding process.
Slow recovery rate of rubber after stress.
The softening of raw rubber by mechanical and atmospheric forces.
A chemical compound that is able to endure polymerization.
A defect that occurs when the rubber does not completely fill out the mold.
Parting Line
A line on the surface of rubber resulting from where the two halves of the mold met.
A material that is used to quicken the softening of rubber compounds under heat or mechanical action.
An insoluble compound that gives rubber its color.
The degree to which rubber will retain deformation.
Chemical reaction in which one or more simple materials are transformed into complex materials that have different properties from the originals.
Reinforcing Agent
A substance that is added to rubber to increase its resistance to the harms of the vulcanization process.
The result when rubber vulcanizes too quickly.
Extra material that leaks from the mold as it closes.
The term for the uniting of two parts of vulcanized rubber to make a whole.
A thermo-setting reaction that involves the use of pressure and heat, and results in highly increased elasticity and strength of materials like rubber.

Diving Deeper – Rubber Molding Applications

To one extent or another, molded rubber products span across every industry. Examples of these industries include: medicine and healthcare, electronics, aerospace, automotive manufacturing, transportation, sports and recreation, EMI shielding and sound management.
Countless products are made using the rubber molding process, due to its precision results. Rubber molded parts can be designed to fit into any piece of equipment without any risk of leakage. In addition, because of the existence and capabilities of synthetic rubber, industries such as health care, can make use of numerous applications while reducing the health risk. For instance, alternative materials are available for people with latex allergies, and intravenous fluids can pass safely through silicone tubing without causing allergic reactions.\

Products Produced from Rubber Molding

Many kinds of complex rubber products are made this way. Examples include: oil and gas components, fluid pumps, rubber diaphragms, customized buttons, vibration absorbers and isolators, rubber seals, rubber grommets, rubber washers, rubber bushings, cable boots, EMI shielding products, surgical instrument parts, blood analysis machines, keypads, electrical connector inserts and rubber sheet.

Rubber Grommets
Rubber grommets are a useful component that is used extensively for industrial, consumer, and commercial purposes. Rubber grommets are made to fit around a hole in a surface, protecting wires or other hardware that must pass through it. Grommets can also protect the hole itself from wear or damage. Rubber grommets can be found protecting wires from becoming disconnected, or aligning the holes in desks which allow safe passage for computer wires.

Rubber Washers and Rubber Bushings
Since many manufacturing machines contain moving parts that can vibrate excessively, rubber washers and rubber bushings are installed to secure these moving parts and absorb vibration in an effort to protect the people operating them.

Rubber Sheet
A rubber sheet is a large, thick sheet that reduces vibration and noise in a machine when placed underneath it. The reduction of vibration and noise can greatly improve overall safety and working conditions.

History of Rubber Molding

Natural rubber has likely been in use in some form or another for a very long time. Specifically, some South American tribes report that their people have been using rubber tree sap to make household items for thousands of years. In addition, we believe that rubber was used by the Mayans as far back as 1600 BC. Rubber molding, though, didn’t really start taking place until after the development of vulcanization. Once scientists learned how to do this, they could process rubber without degrading it.

Before vulcanization, people were using rubber, but with less success. It all began in 1823, when Scottish chemist Charles Macintosh discovered that by applying rubber mixed with a coal-tar byproduct to one cloth, he could glue it to another. The use of rubber products quickly spread across Europe and to the United States. Time and time again, rubber product users found that the rubber (excluding erasers and shoe soles) often deteriorated quickly and stank. Also, it became gummy in hot weather.

This went on until 1839, when American Charles Goodyear learned how to vulcanize the rubber. He learned that if you add Sulphur to the latex rubber, the polymers will stabilize and the rubber will become durable. He received a patent for the vulcanization process in 1844. Nevertheless, this process wasn’t used much until after 1889, when manufacturers began creating rubber bike tires and rubber automobile tires. By the early 1900s, the demand for rubber around the world had skyrocketed, eventually leading to the development of synthetic rubber compounds. Today, less than half of all rubber materials manufactured worldwide are made from natural rubber.

Brothers Isaiah and John Hyatt patented the first rubber injection molding machine in 1872. Over the course of the rest of the 1800s and the 1900s, others made many improvements on this first molding machine. Also, as chemists came up with new kinds of synthetic rubber, like liquid silicone, engineers were able to come up with new ways of molding. For example, in the 1970s, James Watson Hendry invented the gas-powered injection molding machine, which allowed manufacturers to significantly increase their product output.

From the late 20th and early 21st century, one of the most important contributions to rubber molding has been automation. Today, the rubber industry relies on a mixture of CNC technology and CAD programming to create a high volume of custom mold rubber products.

Rubber Molding Materials Process

The various types of rubber that can be molded include natural rubber, as well as synthetic rubber such as neoprene, foam rubber, EPDM, silicone rubber, and liquid silicone rubber. While synthetic rubbers have the same positive qualities as natural rubber, they display other qualities as well. Synthetic rubbers can be made corrosion-resistant, heat-resistant, ozone resistant, inert with certain chemicals, and made with varying degrees of properties such as rigidity, flexibility, durability, and strength.

Natural Rubber
Natural rubber comes from the sap of certain trees, such as some trees of the genera Ficus. Most often, though, it is extracted from the Pará tree (hevea brasiliensis), more commonly known as the rubber tree. Agricultural workers get it by tapping into the tree, just as you would get maple syrup from a maple tree. Rubber producers then mix the sap with formic acid to get it to coagulate. This uncured rubber substance contains latex. For this reason, it is often passed over by manufacturers looking to avoid causing an allergic reaction.

The first synthetic rubber to be produced on an industrial scale was neoprene. Developed by DuPont in the 1930s, it is a general-purpose chloroprene polymer. Manufacturers use it to mold liners, gaskets and various gardening and household items. Neoprene products are susceptible to degradation at the hands of chemicals like acetic acid, turpentine and iodine.

Foam Rubber
Foam rubber is manufactured with foaming agents that make it flexible and air-filled. It may be made from a number of different rubbers, but most often, it is made from polyurethane. Foam rubber can be twisted, scrunched, stretched, pushed or pulled without detriment. It comes in two main types: open cell and closed cell. Open cell foam rubber products feature interconnected pores, while closed cell foam products feature disconnected pores. Think of it this way: Open cell foam is open to others; therefore, its pores are connected. Closed cell foam is closed off to others, so its pores keep to themselves. Also, because closed cell foam pores are not spread out and connected, more are able to fit into the space, making closed cell foam denser.
Open cell foam rubber is used to make automobile trim, automobile seat padding and padding for pillows and mattresses. It is also used as padding in packaging and for noise control. Closed cell foam rubber is used to make thick auto products, insulation, thermal management products, elbow pads, knee pads, gloves, wetsuits, surgical scrubbers, x-ray positioning pads and orthopedic braces.

EPDM, or ethylene propylene diene monomer, is a synthetic rubber with a lot of great qualities. It, for example, has excellent resistance to: steam, ozone, heat and extreme weather. In addition, it provides superior electrical insulation. EPDM is common for use in automotive manufacturing (electrical gaskets and door seals) and building construction (roofing materials). It is also an important component of engine cooling system hoses.


Elastomers are among the most important polymers used in industries for numerous applications. These polymers have elasticity and viscosity; therefore, they are also known as viscoelastic. Silicone rubber is one such elastomer. It is a high-performance rubber that exhibits an unusual blend of properties such as high-temperature resistance and flexibility.

Silicone Rubber
Silicone rubber is a synthetic rubber made up of silicon, oxygen, carbon and hydrogen. It comes in both liquid and solid form. Solid silicone rubber is quite easy to sanitize, making it popular in the food processing, medical and biotech industries. Its structure always consists of an organic moiety coupled to the silicon and a siloxane backbone (silicon-oxygen chain). Both forms are high temperature resistant and remain stable when exposed to temperatures up to 446℉. Because of its heat stability, silicone rubber is popular for use in metal casting. Silicone rubber, however, has poor fuel and mineral oil resistance. For applications involving those substances, fluorosilicone rubber is a good substitute.

Silicone rubber is a very sticky gel or liquid when it is uncured. It must be cured, vulcanized, or catalyzed to become a solid. At the time of manufacturing, this is often done in two stages to create the desired exact shape, followed by a lengthy post-cure phase. It can also be used in injection molding.

Silicone rubber, used throughout industries and homes, is a part of our daily life. It is a stretchy material that is used to make muffin pans, pot holders, food molds, medical devices, jewelry components, and much more. Silicone molds are made from RTV (Room Temperature Vulcanizing) silicone by a combination of parts that results in a chemical reaction, causing the rubber to vulcanize into a non-stick, stretchy, and durable material. Silicone rubber is of many types to be made into different molds for different purposes.

Properties of Silicone Rubber Molds

  • Silicone molds are heat resistant and can be used at 302 °F (150 °C) degrees without any change in performance. They have excellent thermal and thermo-oxidative resistance and a wide operating temperature range.
  • They are also cold-resistant and can retain elasticity even at -76 °F (-60 °C) to -94 °F (-70 °C). They are flexible at lower temperatures due to their low glass transition temperature.
  •  Silicone rubber is flammable, but if a flame retardant is added, it becomes flame retardant and self-extinguishing.
  • Silicone rubber is highly resistant to any electric discharge and remains stable even at high temperatures and frequencies.
  • Other unique properties include being hydrophobic and having the ability to release materials from their surface easily.
  • Exceptional defense against oxygen, ozone, and sunlight.
  • Ability to easily withstand electromagnetic and particle radiation (UV, alpha, beta, and gamma rays).
  • Outstanding non-stick and non-adhesive qualities.
  • Less toxicity.
  • Transparency in optics.
  • Excellent insulating characteristics.
  • Low reactivity.
  • Superb biocompatibility.
  • Superior mechanical qualities.

How is Silicone Rubber made?

  • The silicon atoms in the silicon dioxide compound, silica, must be separated to create silicone.
  • To do this, enormous amounts of quartz sand are heated to extremely high temperatures, frequently up to 1800 °C.
  • After this, the silicone is heated and mixed with methyl chloride in multiple steps. The resulting polymerized siloxane, known as polydimethylsiloxane, is then distilled. The polymerization of polydimethylsiloxane is therefore possible.
  • Many techniques are used to accomplish this, depending on the intended application of the finished product. The catalyst is mixed with required additives, including colors and the raw silicone compound.
  • Afterward, it is either extruded or injection molded. The final step in the manufacturing process is curing.

Applications of Silicone Rubber

Following are some of the industrial applications of silicone rubber:

  • Aerospace – space suit elements
  • Automotive – gaskets and seals
  • Construction – coatings and sealants
  • Electrical and electronics – adhesives and encapsulants
  • Food processing – food molds
  • Medical – medical instrument components such as seals, tubes, and valves
  • Recreation – goggles and mouthpieces

Rubber Molding Process Details

1. Map out details of product to be molded (material, dimensions, shape, thickness, etc.)
2. Design the die or mold cavity you will use to shape the raw rubber, known as stock.
3. Collect the stock.
4. Deposit the stock into whatever machine you use.
5. Allow to cool and harden.
6. Eject the rubber shape.
7. Finish as needed.
Once removed, the mold could have certain imperfections such as seams. If this is the case, the rubber product may have to undergo further processing if necessary. It is possible to add a variety of finishes and textures to the final product to add an aesthetic touch.

Rubber Molding Design

When preparing to mold a part, manufacturers first think about how the product should look, what qualities it must have and its dimensions. By considering these, they can pick a rubber material with which to work, then turn to their computer programming to create a precise design.
Custom rubber molding, especially, custom rubber injection molding, is a very popular choice with customers because, while it is more costly than standard molding, custom molding is still less expensive than alternative rubber manufacturing methods. Custom mold design offers the possibility of shapes, finishes, textures, tolerances and dimensions made unique just for your application.

Rubber Molding Variations and Similar Processes

The types of rubber molding include injection molding, liquid injection molding, insert molding, compression molding, transfer molding and blow molding. All six methods have their similarities; however, injection molding is used more widely than any other method. An alternative method to rubber molding in general is rubber extrusion.

Injection Molding
The first step in the injection molding process involves collecting raw rubber material, known as stock. The stock is then placed into a hopper that is suspended over a conveyance channel. The stock is then released, and processed through a channel that features a large turning screw. By the time the stock reaches the end of the channel, it is completely melted as a result of a combination of the heating elements within the channel, and the friction caused by the screw’s motion. At the end of the channel is a mold cavity into which the molten rubber is injected. The elements of heat and pressure work together to ensure that the molten rubber fills the cavity entirely, down to the very contours of the mold, and is uniformly distributed. The molten rubber is allowed to cool and harden within the mold, and can be safely removed from the mold cavity once it reaches a solid state.

  • It is the most common, robust, and complex process because the products vary in size and application.
  • Material is injected into mold halves with a plunger.
  • This method is best because it has great output production, can be automated, and has short molding cycles.
  • Many types of materials can be used at the same time, and no trimming of product is needed.
  • Trapped air bubbles, flash, and sinks are problems that can be solved by venting.
  • It is best for thin-walled products; therefore, it is used to make small parts and automobile body panels.

Liquid Injection Molding
Liquid injection molding is quite similar to regular injection molding. The difference is mainly that manufacturers use liquid stock as the starting raw material. In addition, the machinery used includes a metered pump that helps regulate and control stock flow. The pump discharges the liquid, which manufacturers then mix with any additives. Once mixed, a nozzle injects the mixed liquid into a shaped mold. The manufacturers then close the mold tightly with clamps and apply the appropriate amount of heat and pressure for creating the product. By liquid injection molding rubber, manufacturers can produce products more quickly, since they do not have to liquify the stock. Also, liquid injection molded products require very little finishing.

  • Liquid injection molding creates products in cavities, and the liquid material is injected into these cavities.
  • In this process, raw materials are mixed mechanically. After the product is hardened, it is ejected from the mold cavity.
  • It is a high-pressure process, has a shorter cure time, and is used to make intricate designs with great precision.
  • This method is used to mass-produce products, with thermal imaging technology employed to identify any errors.
  • It is best to make gaskets, o-rings, keypads, and electronic contacts.

Insert Molding
Insert molding is a type of rubber and plastic injection molding. During insert molding, manufacturers mold or form rubber parts around non-rubber parts, called inserts. Common insert products include knife blades and surgical tubes.
Compression Molding
Compression molded parts are made when the manufacturer pre-weigh, pre-measure and preheats the stock, and then inserts it into a pre-shaped mold cavity. After that, they close the mold, compressing and squeezing the stock until it stretches into it takes on the shape of the mold. Then, they allow it to harden and cool before removing it. The compression molding process is often followed up by secondary processing for the removal of excess material (flash). Through rubber compression molding, manufacturers can make large, intricate products quite inexpensively. However, the results are not always consistent.

  • Preform rubber is placed into heated cavities to create molds.
  • The raw material can be in the form of pre-measured pellets, granules, or powder.
  • The cavities are closed by heated plungers and put under pressure of 15,000psi to 20,000psi.
  • It is an economical method that has a low-to-medium production rate.
  • The cavities should be cleaned properly to avoid any contamination.
  • Seals, o-rings, gaskets, automotive parts, and cushioning pads are products made from this process.

Transfer Molding
Like compression molding, during transfer molding, manufacturers take a pre-weighed and pre-measured rubber stock, or “preform” and insert it into a cavity above the mold, called a “pot.” Once the stock is placed, they press a heavy mechanical ram into it while applying heat. This forces the preform into the mold via a runner and gate system, where it melts. Manufacturers keep the ram in place until the preform takes on the shape of the mold in its entirety. Transfer molding is valued because it allows manufacturers to not only produce precision molded rubber products, but also rubber products bonded to metal surfaces.

  • A plunger puts the material in the heated cavity, and then it is cooled down to take the shape of the mold.
  • The waste created by compression of the mold is then manually trimmed, followed by cryogenic processes, tumbling, or precision grinding.
  • It has a shorter production cycle and a tighter dimensional tolerance.
  • This process is used to make smaller, more complex, and more detailed parts.

Blow Molding
Rubber blow molding is a molding process by which hollow rubber products are formed. It involves the use of a parison (tube-like plastic shape with a hole in one end) or preform. To expand the part, manufacturers clamp the parison to a mold and then blow compressed air into the parison hole. As the rubber expands, it touches the mold and takes on its shape. After it cools and hardens, manufacturers open the mold and eject the newly formed part.

Liquid Silicone Rubber (LSR)

Liquid silicone rubber is a low viscosity, high purity thermoset elastomer that maintains its mechanical qualities throughout a wide temperature range, i.e., from -50 °C to 250 °C. This heat-cured elastomer is a great option if you want outstanding optical clarity and long-term endurance in a demanding environment (with high temperatures, UV exposure, etc.).

Injection molding is the only method used to produce liquid silicone rubber, which is heat-cured while it is being molded. The primary benefit of LSR is the potential to combine several pieces into one, which allows for significant cost savings. In addition, liquid silicone rubber can lead to significantly increased production by using smaller equipment and eliminating material waste.

Rubber Extrusion
Rubber parts can alternatively be produced through rubber extrusion. However, extruding machines have much more limited capabilities. An extruder only has control over the X and Y axes, and are thus much more suited for the production of simpler rubber products such as rubber baseboards or rubber sheets. Rubber molding allows from design control over three axes due to the process involving a molding cavity instead of a die.

Extrusion of Raw Material

  • Extrusion is done by creating uncured raw material with the help of dye to form a uniform cross-sectional-shaped product.
  • The raw material is passed through the extruder, which uses screws for temperature fluctuation and rotation.
  • After shaping the product into the required shape, it is washed and cooled by air or water and then cut into the final product.
  • The extrusion process is low-cost, takes less time, and produces a bulk of products.
  • It is difficult to maintain tolerance criteria, and per-part price varies due to the complexity of the dye.
  • It is best for the production of gaskets, tubing, and seals.

Product Calendering

  • It is a speedy, continuous sheeting process that uses a number of rollers to press the semi-liquid material into a hard sheet.
  • The products are then coated onto fabrics.
  • It is essential to set an optimum temperature for rollers to avoid overheating and sticking.
  • Creeping of the product is also a concern in calendering.
  • It is used to make dye sheet cuts and thin sheets of material.

Benefits of Rubber Molding

Rubber molding offers quite a few benefits, especially when compared to other rubber forming techniques. First, rubber molding offers versatility. This is because rubber molding manufacturers can make use of so many different types of rubber-based raw materials, and also because they can produce a wide range of complex custom parts. Second, rubber molding is efficient and reduces production time. It is also well-paired with large volume runs.

Rubber Dictionary