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The use of specially created ceramic materials for enhancing human body protection against ballistic threats, such as bullets or projectiles, is known as “ceramics for body protection.” These ceramics, sometimes known as ballistic ceramics or armour ceramics, are used to create body armour systems, such as helmets, vests, and vehicle armour.
Ceramics designed for bodily protection often have high levels of toughness, strength, and hardness while yet being relatively light. They are made to withstand and diffuse projectile energy, lessening the impact and the likelihood of injury to the wearer.
In order to build composite structures that offer improved protection against both ballistic threats and other forms of impacts, ceramic components are frequently mixed with other materials, such as aramid fibres or polyethylene, in body armour systems. The backing material absorbs and dissipates the projectile’s remaining energy while the ceramics act as a front layer to break up and disperse its kinetic energy.
The Ceramics for Body Protection accounted for $XX Billion in 2023 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2024 to 2030.
A cutting-edge body protection system created by Morgan Advanced Materials is Ceramic Armour with Dyneema backing. The excellent ballistic capabilities of ceramic materials are combined with Dyneema fibres’ remarkable strength and durability.
The strike face in this design is made of a ceramic substance like alumina or silicon carbide. Ceramics are recognised for their extreme hardness and capacity to efficiently dissipate projectile energy. Layers of Dyneema fabric are combined as a backing material to improve the performance of the armour.
For their exceptional strength-to-weight ratio and exceptional resistance to impact, abrasion, and chemicals, Dyneema fibres are renowned. The armour is made more flexible and capable of absorbing energy by adding Dyneema backing. The Dyneema fibres efficiently distribute and dissipate projectile kinetic energy, lowering the chance of penetration and the wearer’s risk of injury.
