What is Polycarbonate?
Polycarbonate materials are referred to as groups of thermoplastic polymers that have a chemical structure containing the carbonate groups. Polycarbonates that are used in engineering need to be strong, tough materials, and some grades are optically transparent. They can easily be moulded, worked and thermoformed. Polycarbonates have a large number of applications due to their properties. It does not have a unique resin identification code and a monomer bisphenol which is also abbreviated as BPA and is present in many of the products that are made from polycarbonate. Before proceeding further with polycarbonates let us know a little bit about carbonates as well.
Introduction to Carbonates
In chemistry, carbonate is characterized by the presence of carbonate ion that can be concluded as a polyatomic ion with the molecular formula of CO32-and is known as the salt of carbonic acid (H2CO3). As the organic compound contains the carbonate group that is C(=O)(O–)2, it may also be referred to as carbonate ester. This term is also used for the description of the carbonation process which is referred to as a process in which the concentration of the carbonate and bicarbonate ions are increased in water to produce carbonated water or other aerated drinks. This is either done by passing carbon dioxide into the liquid by pressure or by mixing the carbonate or bicarbonate salt in water.
In geology and mineralogy, the term carbonate is referred to as both carbonate minerals and carbonate rocks which are also formed from carbonated minerals that mainly comprises and is dominated by carbonate ions. In chemically precipitated sedimentary rock carbonate minerals are extremely varied and ubiquitous. The most common ones are the calcite and the calcium carbonate CaCO3 which is the main constituent of limestone. They are also considered as the main component of mollusc shells and coral skeletons whereas dolomite, Siderite or iron carbonate (FeCO3) and calcium magnesium carbonate CaMg(CO3)2 are the main iron ores. Since ancient times, potassium carbonate has been used for the purpose of cleaning as well as for preservatives. In modern times it is used for the manufacturing of glasses. It has a wide range of industrial applications such as preparing Portland cement and lime manufacturing, iron smelting and composing ceramic glaze and more.
Some of the typical physicochemical properties of polycarbonates are as follows:-
Physical and Chemical Properties
Types of polycarbonate sheet
The polycarbonate sheets are thermoplastic and transparent sheets that are incredibly tough and absorb minimal moisture, making them resistant to impact damage as well as water damage. They are also chemical retardant as well as a flame retardant in nature. Thus some of the major types of polycarbonate sheets that are most widely used for industrial, commercial as well as housing purposes are given below:-
Solid And Textured Polycarbonate Sheets: These sheets are generally made up of high-quality polycarbonate and have a strength that is 250 times the strength of the glass of the same thickness. This is a transparent polycarbonate sheet that is as clear as glass and allows 90% of the sunlight without letting harmful UV radiation enter through it. They possess thermal and chemical resistance and have the capability to withstand harsh weather conditions.
Corrugated Polycarbonate Sheets: Corrugated sheets are stronger as compared to their flat counterparts. For commercial and industrial applications, warehouses along with residential houses are considered the most suitable polycarbonate sheet. The people who are concerned with environmental issues rely on this kind of sheet as it enhances daylight harvesting. They provide better insulation from heat as well as cold as compared to the glass sheets along with maintaining the optical properties for a longer period. They are also completely water-resistant.
Multiwall Polycarbonate Sheet: Multiwall polycarbonate resin ensures high impact strength with excellent transparency and is lightweight. Along with advanced heat reflection and light transmission, they come with a glazing system that provides outstanding flexibility in design. They are also available mostly ranging from twin walls to five walled structures that vary the thermal insulation and therefore used in various applications. In order to ensure optimum illumination, they ensure the passage of a maximum of 80% and a minimum of 25% light transmission along with a lower heat transmission level. They retain their mechanical properties at temperatures between -40oC to +120oC and therefore are capable of tolerating extreme weather conditions. They are highly energy-efficient and can save capital costs in terms of air conditioning and heating.
Lexan Polycarbonate Sheet: They are required at large in industrial, commercial and residential applications for their properties. They are preferred because they offer excellent clarity with attractive aesthetic properties and high impact strength. They can be formed or designed easily. Along with ease of thermoforming or cold forming, the opaque sheets provides excellent impact performance and stiffness. Along with the wide colour variety, they offer a consistent high-quality surface and cost-effective part differentiation. They also have excellent flame-retardant properties.
Polycarbonate Uses
Polycarbonate uses have raised in following years and some of their major applications are listed below:-
Fencing and Protective Barrier: Along with being extremely durable and flexible they also extend the high impact resistance heating. These are also used for the construction of a variety of different types of fencing protective barriers and partitions as they have very high strength. In banks, grocery stores and other establishments they are commonly used as bulletproof barriers. Polycarbonates are also the material of choice that provides protective barriers in hockey arenas and ice skating fields.
Storefront Windows: As it allows a lot of sunlight with an incredible UV protection capability they are also commonly used for or banks storefront windows and other public-facing businesses. Its transparency also allows the businesses in displaying their products so that the passerby can have a look at what the store has to offer. They do not overheat the interior and cause Sun damage for declaration of products.
Safety Glasses: Along with sustaining a large amount of impact the polycarbonate plastics are also heat resistant, chemical resistant and flame retardant. Therefore this material is highly preferred for manufacturing high-performance safety goggles and glasses that have a wide variety of applications in science labs, construction sites, woodworking, welding, mining and many more.
Building and Constructions: The polycarbonate plastic is 200 times stronger and more impact resistant than the glass of the same thickness. It is also more flexible and affordable than glass and can also be moulded and customised to fit the requirement. Therefore these days the polycarbonate plastic is used as an alternative to glass in many construction applications and buildings. For transparent walkways and skylights in buildings, polycarbonate has become the top choice because of its incredible strength, insulation capability and flexibility.
Room Dividers: Another biggest advantage of polycarbonate plastic is that it is highly lightweight in nature compared to other elements such as glass. This makes it very easy for polycarbonate plastic to be transported and installed at any place wherever they are needed. Therefore many big and small room dividers polycarbonate plastic is the topmost choice. They are mostly used for dividing the office cubicles or as a sneeze guard in restaurants and grocery stores.
FAQs on Polycarbonate
1. What is polycarbonate (PC)?
Polycarbonate (PC) is a group of strong, tough thermoplastic polymers. Chemically, they belong to the polyester family, as their structure contains carbonate groups (-O-(C=O)-O-). Polycarbonates are naturally transparent and have extremely high impact resistance, making them a durable material for a wide range of applications.
2. What are the monomers used to synthesise polycarbonate?
Polycarbonate is typically synthesised through the condensation polymerisation of Bisphenol A (BPA) and a carbonate source like phosgene (COCl₂) or diphenyl carbonate. The reaction links the BPA molecules together with carbonate groups, eliminating a small molecule like HCl or phenol in the process. For more details on its monomer, you can refer to the page on Bisphenol A.
3. What are the key properties of polycarbonate?
Polycarbonate is valued for its unique combination of properties, which include:
High Impact Strength: It is virtually unbreakable, making it resistant to shattering.
Optical Clarity: It is naturally transparent and can transmit light almost as well as glass.
Temperature Resistance: It maintains its properties over a wide range of temperatures and has good heat resistance.
Lightweight: It is significantly lighter than glass, which is an advantage in many applications.
Dimensional Stability: It holds its shape well and has low moisture absorption.
4. What are some common real-world examples of polycarbonate use?
Due to its durability and clarity, polycarbonate is used in many everyday items. Some common examples include electronic device casings (laptops, phones), automotive components (headlight covers), safety glasses and visors, reusable water bottles, and optical media like Compact Discs (CDs) and DVDs.
5. Why is polycarbonate often used to make 'bulletproof glass'?
Polycarbonate's exceptional toughness and ability to absorb kinetic energy without fracturing make it a primary component in bullet-resistant laminates, often referred to as 'bulletproof glass'. A common brand name for this material is Lexan. Instead of shattering on impact like regular glass, it deforms and absorbs the energy from a projectile. For this reason, laminated polycarbonate is a key material in security applications. Learn more about the polymer used in bullet proof glass.
6. How does polycarbonate compare to acrylic (PMMA), another common glass substitute?
While both are transparent plastics used as glass alternatives, they have key differences:
Impact Strength: Polycarbonate has significantly higher impact strength than acrylic and is much less likely to shatter.
Hardness: Acrylic is harder and more scratch-resistant than polycarbonate.
Cost: Polycarbonate is generally more expensive than acrylic.
Flammability: Acrylic is more flammable, whereas polycarbonate has better flame retardant properties.
7. Why is polycarbonate classified as a thermoplastic polymer?
Polycarbonate is classified as a thermoplastic because its chemical structure consists of long polymer chains held together by weak intermolecular forces (van der Waals forces). When heated, these forces are easily overcome, allowing the polymer to soften and melt into a liquid form that can be remoulded. Upon cooling, it solidifies again without any change to its chemical composition. This ability to be repeatedly melted and reshaped is the defining characteristic of thermoplastics.
8. What are the safety concerns associated with polycarbonate, especially regarding Bisphenol A (BPA)?
The primary safety concern with polycarbonate is related to the potential for trace amounts of its monomer, Bisphenol A (BPA), to leach out, especially when the plastic is heated or comes into contact with acidic or basic substances. BPA is an endocrine disruptor, and its potential health effects have led to the development of 'BPA-free' plastics, particularly for food and beverage containers like baby bottles and water bottles.
9. What does the 'Type 7' recycling code on polycarbonate products mean?
Polycarbonate is labelled with the resin identification code #7, which stands for 'Other'. This category is for all plastics that do not fit into the other six classifications (like PET, HDPE, etc.). Because this category includes a mix of different plastics, #7 products, including polycarbonate, are generally not accepted in standard municipal recycling programs. You can explore more about types of plastic and their recycling codes on our page.
