Blasting cap

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Class B blasting caps
Class B blasting caps

A blasting cap is a small explosive device generally used to detonate a larger, more powerful explosive such as dynamite.

Blasting caps come in a variety of types, some of which are: non-electric caps, electric caps and fuse caps. They are used in commercial mining and are set off by a dynamo device which generates a short burst of current in a line long enough to ensure safety.

The need for blasting caps arises due to sensitivity issues of an explosive compound. All explosive compounds have a certain amount of energy required to create detonation. If an explosive is too sensitive, it may detonate unexpectedly, and so the most practical explosive compound is one that is safe to handle, and won't detonate if accidentally dropped or mishandled. However, such explosives are hard to ignite intentionally as well. A blasting cap contains an easy-to-ignite explosive that provides the initial activation energy to start a detonation in a more stable explosive.

Most blasting caps contain what is called a primary explosive. A primary explosive is a high explosive compound that will explode from flame, heat or shock. A blasting cap may also contain a booster – another explosive to make the cap more powerful, and thus more reliable for detonating secondary explosives.

Explosives commonly used in blasting caps include mercury fulminate, sodium azide, lead azide, and tetryl.

Because of their size and appearance, blasting caps are sometimes not recognized as explosives, leading to injuries.

Contents

[edit] Types of Blasting Caps

[edit] Pyrotechnic Fuse Blasting Caps

The oldest and simplest type of cap, fuse caps are a metal cylinder, closed at one end. From the open end inwards, there is first an empty space into which a pyrotechnic fuse is inserted and crimped, then a pyrotechnic ignition mix, a primary explosive, and then the main detonating explosive charge.

The primary hazard of pyrotechnic blasting caps is that for proper usage, the fuse must be inserted and then crimped into place by crushing the base of the cap around the fuse. If the tool used to crimp the cap is used too close to the explosives, the primary explosive compound can detonate during crimping. A common hazard is unsafe blasters crimping caps with their teeth; an accidental detonation can cause serious or fatal injuries to the mouth and head. Proper recommended procedure is to position the crimping tool and tighten it up, then hold it behind yourself slightly below waist level while actually crimping. While embarrassing, minor injuries to the buttocks are the location least likely to cause serious or permanent incapacitation.

Fuse type blasting caps are still in active use today. They are the safest type to use around certain types of electromagnetic interference, and they have a built in time delay as the fuse burns down.

[edit] Solid Pack Electric Blasting Cap

Solid pack electric blasting caps use a thin bridge wire in direct contact (hence solid pack) with a primary explosive, which is heated by electric current and causes the detonation of the primary explosive. That primary explosive then detonates a larger charge of secondary explosive.

Some solid pack fuses incorporate a small pyrotechnic delay element, up to a few hundred milliseconds, before the cap fires.

[edit] Match or Fusehead Electric Blasting Cap

Match type blasting caps use an electric match (insulating sheet with electrodes on both sides, a thin bridgewire soldered across the sides, all dipped in ignition and output mixes) to initiate the primary explosive, rather than direct contact between the bridge wire and the primary explosive. The match can be manufactured separately from the rest of the cap and only assembled at the end of the process.

Match type caps are now the most common type found worldwide.

[edit] Exploding Bridgewire Detonator or Blasting Cap

This type of detonator was invented in the 1940s as part of the Manhattan project to develop nuclear weapons. The design goal was to produce a detonator which acted very rapidly and predictably. Both Match and Solid Pack type electric caps take a few milliseconds to fire, as the bridge wire heats up and heats the explosive to the point of detonation. Explosive bridgewire or EBW detonators use a higher voltage electric charge and a very thin bridge wire (1 mm long, 0.04 mm diameter). Instead of heating up the explosive, the EBW detonator wire is heated so quickly by the high firing current that the wire actually vaporizes and explodes due to electric resistance heating. That electrical driven explosion then fires the detonator's initiator explosive (usually PETN).

Some similar detonators use a thin metal foil instead of a wire, but operate in the same manner as true bridgewire detonators.

In addition to firing very quickly when properly activated, EBW detonators are safe from stray static electricity and other electrical current. Enough current and the bridge wire may melt, but it is small enough that it cannot detonate the initiator explosive unless the full, high voltage high current charge passes through the bridgewire. EBW detonators are used in many civilian applications where radio signals, static electricity, or other electrical hazards might cause accidents with conventional electric detonators.

[edit] Slapper Detonator or Blasting Cap

Main article: Slapper detonator

Slapper detonators are an improvement on EBW detonators. Slappers, instead of directly using the exploding foil to detonate the initiator explosive, use the electrical vaporization of the foil to drive a small circle of insulating material such as PET film or kapton down a circular hole in an additional disc of insulating material. At the far end of that hole is a pellet of conventional initiator explosive.

The conversion efficiency of energy from electricity into kinetic energy of the flying disk or slapper can be 20-40%.

Since the slapper impacts a wide area (roughly one mm across) of the explosive, rather than a thin line or point as in an exploding foil or bridgewire detonator, the detonation is more regular and requires less energy. Reliable detonation requires raising a minimum volume of explosive to temperatures and pressures at which detonation starts. If energy is deposited at a single point, it can radiate away in the explosive in all directions in rarefaction or expansion waves, and only a small volume is efficiently heated or compressed. The flyer disc loses impact energy at its sides to rarefaction waves, but a conical volume of explosive is efficiently shock compressed.

Slapper detonators are used in nuclear weapons. These components require large quantities of energy to initiate, making them extremely unlikely to accidentally discharge.

[edit] Laser Ordnance Initiators

Another type of initiator that is rarely seen requires the use of a laser to initiate a carbon-doped explosive via a fiber optic. These initiators are highly reliable, and offer a number of advantages, primarily in that unintentional initiation is made very difficult. Without the correct laser initiation system, or a completely independent initiation system, these components are not capable of being controlled remotely.

[edit] History

The first blasting cap or detonator was demonstrated in 1745, when a Dr. Watson of the Royal Society showed that the electric spark of a Leyden Jar could ignite black powder.

In 1750, Benjamin Franklin in Philadelphia made a commercial blasting cap consisting of a paper tube full of black powder, with wires leading in both sides and wadding sealing up the ends. The two wires came close but did not touch, so a large electric spark discharge between the two wires would fire the cap.

In 1822 the first hot wire detonator was produced by Dr Robert Hare. Using one strand separated out of a multistrand wire as the hot bridge wire, this blasting cap ignited a pyrotechnic mixture (believed to be potassium chlorate/arsenic/sulphur) and then a charge of tamped black powder.

In 1867, Alfred Nobel introduced the first Pyrotechnic Fuse blasting cap, using mercury fulminate to detonate dynamite. In 1868, H. Julius Smith introduced a cap that combined a spark gap ignitor and mercury fulminate, the first electric cap able to detonate dynamite.

In 1875, Perry "Pell" Gardiner and Smith independently developed and marketed caps which combined the hot wire detonator with mercury fulminate explosive. These were the first generally modern type blasting caps. Modern caps use different explosives and separate primary and secondary explosive charges, but are generally very similar to the Gardiner and Smith caps.

Electric match caps were developed in the early 1900s in Germany, and spread to the US in the 1950s when ICI International purchased Atlas Powder Co. These match caps have become the predominant world standard cap type.

[edit] See also

[edit] External links

[edit] References

Cooper, Paul W., Explosives Engineering, New York: Wiley-VCH, 1996. ISBN 0-471-18636-8