DE1228541B - Delay ignition system - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

GERMAN

PATENT OFFICE

EDITORIAL

Int. Cl .:

C06c

German class: 78 e -4

Number: 1228 541

File number: P 30862 VI b / 78 e

Filing date: December 27, 1962

Opening day: November 10, 1966

Delay ignition system

U.S. Patent 2,982,210 discloses a fuse with a core of detonating explosive, Load weight 0.1062 to 0.4248 g / running meter, which is described with one or more layers a reinforcing and / or water-protecting material housed in a metal sleeve is. Because it propagates a detonation pulse without explosiveness and not the dangers of electrical ones Has detonators, this cord often replaced conventional detonation fuses and in shooting work electric detonators. Even this cord does not ignite all types of explosives that are commonly used used in shooting, as a result, relief measures are necessary.

In many cases it is now desirable to delay the ignition of the main charge. For this Purposes are delay detonators with a delay set between the detonating cord and the main charge common. These delay detonators must have a high level of operational reliability, even below high water pressures and possible shock loads.

There is already an ignition system (Canadian patent specification 627 435) has become known in which At the bottom of a metallic shell there is an explosive charge on which a delay set is seated. In contact with the delay set, a low-energy detonating fuse is over Beads held in the sleeve. This fuse lies on a diaphragm, which in turn is the Surrounding ignition charge. It has now been found that such a delay detonator is not the required one Has operational reliability. As is well known, these detonators are assembled on the spot, and each with the required length of fuse. The endless fuses in simply cut off the appropriate length. This cutting does not produce a sharp cutting line and thus no exact seating on the ignition charge is guaranteed. Hence there comes a certain Uncertainty factor due to incorrectly cut off area of the fuse or not detonating cord that is sufficiently tight on the primer.

The delay ignition system according to the invention now eliminates this uncertainty and has an outstanding Operational reliability after the low-energy detonation and the developed in this system Pulse of the fuse is increased by detonation of a booster charge so far that the Detonation front hitting the end of the capsule ensures reliable ignition of the shock-sensitive La applicants:

E. I. du Pont de Nemours and Company,

Wilmington, Del. (V. St. A.)

Representative:

Dr.-Ing. F. Wuesthoff, Dipl.-Ing. G. Pulse
and Dr. E. Frhr. v. Pechmann, patent attorneys,
Munich 9, Schweigerstr. 2

Named as inventor:

Ross Jay Miller,

Franklin Lakes, N. J. (V. St. A.)

Claimed priority:
V. St. v. America December 27, 1961
(162412)

guaranteed. A special feature of the delay ignition systems according to the invention is also It can be seen that if the low-energy detonation fuse is not stored exactly exactly or if the end of the junction is not completely clean, the detonation will continue to propagate achieved when there is an air gap of up to about 3.2 mm. In the ignition system according to the invention infiltration of water is not possible. The invention Detonators therefore have a high level of security, since they are not mechanical Exposure can still be desensitized by penetration of water.

The invention thus relates to a delay ignition system consisting of a low-energy detonation fuse in connection with a delay detonator, the latter consisting of a detonator case, those starting from the ground up a secondary set 7, a transmission set 8, a delay set 9 and an empty tube 10, which is closed at the top, with a shock and / or pressure-sensitive one Contains initial sentence 12 in the closed head part, and is characterized in that between the low-energy detonation fuse inserted in the detonator and the closed head part 16 of the empty tube 10 a booster charge 13, optionally in a tight tube 14 which fits into the detonator cap.

609 710/92

i 228

In a preferred embodiment of the invention With delay ignition system, the booster charge has "essentially" the same composition like the fuse, but with a larger load weight, which however is not sufficient, p commercial dynamite · to rzijnd into which the Detonator is to be used. Between delay block 'and' transfer block can be in According to a special embodiment of the invention, an auxiliary delay set is also located in a carrier.

The booster charge expediently consists of the same detonating explosive with im essentially the same blasting properties as the core of the low-energy detonation fuse, however, it is used with a higher cargo weight, e.g. B. 0.4248 to 1.562 g / rfd. m. The booster charge is in place expediently in a container for lighter loading and to prevent violent reactions z. B. made of lead.

The usual substances can be used as a shock and / or pressure-sensitive initial sentence, for example Lead typhnate, mixtures of boron and red lead, mixtures of magnesium, barium peroxide and Selenium, mixtures of bismuth, selenium and calcium chlorate, mixtures of lead typhnate, tetrazene and Glass powder and the like. To prevent damping, the initial charge should be kept as small and thin as possible , it is therefore advisable to have a charge in the order of magnitude of a layer thickness between 0.254 and 0.762 mm.

The clearance between the initial record and the delay record can be changed to e.g. B. to set the ignition pulse sharply, by application an empty tube of different lengths and wall thicknesses. In general, the tube has an empty tube a length of not more than 12.7 mm, having a greater clearance between initial set and deceleration rate may lead to unreliable propagation of the detonation could.

Exothermically reacting mixtures of a metal and an oxidizing agent serve as the delay set, as they are usually used with gasless delay igniters. Mixtures are preferred of boron, red lead and secondary lead phosphite, magnesium and barium oxide and selenium or silicon and red lead. Mixtures that burn off at a constant rate are for example those of barium peroxide and selenium, bismuth and selenium and potassium chlorate, lead and selenium or Magnesium and barium peroxide. The mass for the delay set can optionally be granulated be e.g. B. with neoprene, rubber, shellac, polyethyleneglycol, Thiokol and Carbowaxes, whereby loading is generally facilitated.

Heat-sensitive substances such as lead azide, diazodinitrophenol or Mercury fulminate can be applied.

Pentaerythritol tetranitrate, cyclotrimethylene trinitramine, lead azide, nitroannitol, Use cyclotetramethylenetetranitramine and the like.

The explosives to be used in each case are not for the delay detonators according to the invention critical, provided that they work in the desired way!

The tamping of the individual sets is done with appropriately shaped bolts that, for. B. conical, flat, can be pointed or bell-shaped, as is common practice. "■. '"'. ,

The invention is explained in more detail on the basis of the figures:

Fig. 1 shows a section through the inventive Delay ignition system and

F i g. 2 one with a longer delay.

According to Fig. 1 is located in a detonator case 1 with a closed bottom from bottom to top of the secondary set 7 and reaching into it the transfer set 8 made of a heat-sensitive explosive. The delay sentence is arranged on this 9 in the form of an exothermic burning mixture, the empty tube 10 with closure in Shape of an anvil 18 and air channel 19 in the cylinder capsule 11 with head part 16. In the head part 16 of the Capsule 11 is the initial set 12 made of a shock and / or pressure-sensitive explosive. At the head part 16 closes a booster charge 13 within a suitable tube 14 on this filling of the detonator shell 1 then becomes the low-energy detonation fuse 2 from core 3, Metal sleeve 4 and coating 5 pushed in and held in place in sleeve 1 with the aid of beads 6.

F i g. 2 shows another embodiment of the delay ignition system according to the invention. The first Difference from the embodiment of FIG. 1 is that in the cylinder sleeve 11, in whose head part 16 is the initial sentence 12, instead of the empty tube of the embodiment of FIG Fig. 1, a sleeve 10 'is arranged, the shell shape of the sleeve 11 and thus to the Sleeve 1 connects and forms the anvil 18 with its bottom part. The second difference is in that between the delay set 9 and the transfer set 8 in a modification of the Embodiment of FIG. 1 still a carrier 15 with an additional auxiliary delay set 17 is located.

When the fuse 2 is ignited, the impulse that is triggered by the detonation of the core 3, transferred to the booster charge 13 and thus caused it to ignite; it strengthens now the first impulse. The detonation front hits the head part 16, which now has sufficient impact energy acts on the initial set 12 above the anvil 18. The combustion products from the initial sentence are passed on via the air channel 19 within the empty tube 10 to the delay set 9 and cause its ignition. From there, the ignition is set via the heat sensitive transfer rate 8 finally brought to the secondary set 7.

An ignition system according to FIG. 1 can be designed so that a delay between 1 and 100 msec is achieved. The delay time can be set with the layer height of the delay set and its Compaction after its burning time is proportional to the layer thickness. Longer delay times achieved one with the embodiment of FIG. 2, up to about 20 seconds. This is achieved with the help of the auxiliary delay theorem 17, which is only ignited after the delay set 9 has burned down and finally leads to the ignition of the transfer set 8.

The sleeve 1 must have sufficient strength, so that a deformation or destruction already is prevented by burning off the parts of the system arranged in front of the secondary set.

On the other hand, it must not be so firm that the effect of the secondary clause is impaired. at a booster charge of approximately 0.1296 to 0.3260 g is therefore a sleeve made of aluminum or a copper alloy have a thickness at the capsule end of about 0.254 to 0.762 mm. Lesser ones Thick ones could damage the case during loading. Set greater thicknesses a deformation already provides an inappropriately high resistance.

The invention is explained in more detail using the following examples:

example 1

Ten delay detonators according to the embodiment from FIG. 1 manufactured.

Capsule shell: 50.8 mm long, 6 mm a. D., 5.59 mm I.W .; Secondary set: 0.324 g pentaerythritol tetranitrate, stuffed under a pressure of 90 kg; Transfer kit: 0.13 g lead azide stuffed under a pressure from 90 kg; Delay rate: 0.324 g mixture of boron and red lead 2:98, stuffed under a pressure from 45 kg.

Cylinder sleeve: 19.35 mm long, open at the lower end, 5.588 mm a. D., 4.826 mm 1st W., bottom thickness 0.457 mm; Initial rate: 0.0648 g, mixture of boron and red lead 2:98; Empty lead tube, 19.05 mm long, 4.75 mm a. D., bore 1.7 mm; Tube for the amplifier kit: 6.15 mm long, 5.512 mm a. D.

Booster charge: 7.387 mg pentaerythritol tetra: nitrate stuffed under a pressure of 45 kg; Low-energy detonation fuse: 0.4248 g / lfd. m Pentaerythritol granitrate.

Delay time: 56.7 msec.

Example 2

Ignition system for longer delay according to FIG. 2. capsule shell made of aluminum according to example 1, loaded with pentaerythritol tetranitrate as the secondary charge and lead azide as the transfer charge. It became a Auxiliary delay set applied, consisting of a carrier, 12.7 mm long, wall thickness 1.6 mm, with delay charge, mixture of boron and red lead and secondary lead phosphite in a mixing ratio 1.5: 23.5: 75. In the bottom of a bronze case Bottom thickness 0.457 mm, 12 mm long, 0.065 g of a mixture of boron and red lead 2:98 - granulated with Thiokol - loaded. This bronze sleeve went over an aluminum sleeve, 11.43mm long, turned upside down and folded in. The sleeves connected in this way were then inserted into the ignition

o capsule sleeve inserted. Carrier for the booster charge: 12.7mm long, 5.512mm a. D., 4.826 1. W., with lead azide in the bore, plugged under one Pressure of 90 kg, detonation fuse: 0.2124 g / running meter, delay time: 1.09 seconds.

Lead typhnate, a mixture of boron and red lead, can be used as an initial sentence for similar results 2:98, a mixture of magnesium and barium oxide and selenium 30:35:35 or a mixture of bismuth and Apply potassium chlorate 62: 35: 3.

Claims (1)

Claim: Delay ignition system, consisting of a low-energy detonation fuse in connection with a delay detonator, the latter consisting of a detonator shell, the starting from the ground a secondary set (7), a transmission set (8), a delay set (9) and an empty tube (10) which is closed at the top and is sensitive to impact and / or pressure Contains initial sentence (12) in the closed head part, characterized in that that between the low-energy detonation fuse inserted in the detonator and the closed head part (16) of the empty tube (10) a booster charge (13), optionally arranged in a tube (14) fitting tightly into the detonator. Considered publications: German patents No. 948 039, 842 313,
506 018, 422 523. 1 sheet of drawings 609 710/92 11.66 © Bundesdruckerei Berlin