All of you must have witnessed the use of hand grenades either in action movies or games. The most fascinating fact about them is that they are small and deadly at the same time. This lead to the curiosity in me to know above the chemistry involved the functioning of grenades. Let’s find it out,
What are Grenades?
Grenade is a small explosive, (chemical, or gas bomb) that is used at short range combats. The word grenade probably derived from the French word for pomegranate, because the bulbous shapes of early grenades resembled that fruit. Grenades came into use around the 15th century and were found to be particularly effective when exploded among enemy troops in the ditch of a fortress during an assault. They eventually became so important that specially selected soldiers in 17th-century European armies were trained as grenade throwers or grenadiers. After about 1750, grenades were virtually abandoned because the range and accuracy of firearms had increased, lessening the opportunities for close combat.
The most common type of grenade on the battlefield is the time-delay fragmentation anti-personnel hand grenade. The primary function of this grenade is to kill or maim nearby enemy troops. To ensure maximum damage, the grenade is designed to launch dozens of small metal fragments in every direction when it explodes.
These sorts of grenades, which played a major role in World War I, World War II, Vietnam, and many other 20th century conflicts, are designed to be durable, easy to use and easy to manufacture. The conventional design uses a simple chemical delay mechanism. The diagram below shows a typical configuration of this system, dating back to the first World War.
The outer shell of the grenade, made of serrated cast iron, holds a chemical fuze mechanism, which is surrounded by a reservoir of explosive material. The grenade has a filling hole for pouring in the explosive material.
The Mechanism of a Hand Grenade
The firing mechanism is triggered by a spring-loaded striker inside the grenade. Normally, the striker is held in place by the striker lever on top of the grenade, which is held in place by the safety pin. The soldier grips the grenade so the striker lever is pushed up against the body, pulls out the pin and then tosses the grenade.
Here’s what happens inside once the grenade is released:
- With the pin removed, there is nothing holding the lever in position, which means there is nothing holding the spring-loaded striker up. The spring throws the striker down against the percussion cap. The impact ignites the cap, creating a small spark.
- The spark ignites a slow-burning material in the fuze. In about four seconds, the delay material burns all the way through.
- The end of the delay element is connected to the detonator, a capsule filled with more combustible material. The burning material at the end of the delay ignites the material in the detonator, setting off an explosion inside the grenade.
- The explosion ignites the explosive material around the sides of the grenade, creating a much larger explosion that blows the grenade apart.
- Pieces of metal from the outer casing fly outward at great speed, embedding in anybody and anything within range. This sort of grenade may contain additional serrated wire or metal pellets for increased fragmentation damage.
Time-delay grenades are very effective, but they do have some significant disadvantages. One problem is their unpredictability: In some chemical fuzes, the delay time may vary from two to six seconds. But the biggest problem with time-delay grenades is that they give the enemy an opportunity to counterattack. If a soldier doesn’t time a grenade toss just right, the enemy may pick it up and throw it back before it explodes.
For this reason, soldiers must use impact grenades in certain situations. An impact grenade explodes wherever it lands, so there is no chance for the enemy to throw it back. In the next section, we’ll see how this sort of grenade works.
Video Courtesy – ” Copperpot Gaming “