BE1029006B1 - Micro-initial explosive for the detonator - Google Patents

Abstract

The present invention relates to a micro-initiating explosive. The present invention includes more than one high explosive and more than one primer. The high explosive contains hexogen and PETN; wherein the initiating explosive comprises dinitrodiazophenol, lead azide, lead trinitroresorcinol, nickel hydrazine nitrate and cadmium perchlorate tricarbohydrazide, and wherein more than one high explosive and more than one initiating explosive are mixed and used. In addition, a binder and a surfactant can be added. The advantage is that compared to conventional detonators, the charge quantity of the initiating explosive can be reduced by 30-60% and the cost can be reduced by 20-30% compared to current detonators, while improving safety when assembling the detonator, and Explosive power and flame sensitivity are guaranteed while reducing sensitivity to static electricity, friction, shock, light and heat, improving the safety of the detonator during the manufacturing, transportation, storage and use processes.

Description

Micro-initial explosive for the detonator

TECHNICAL FIELD The present invention relates to an explosive for the detonator, particularly a micro-initiating explosive.

BACKGROUND ART At present, the initiating explosives are used in the production of all industrial and military detonators, and the consumption amount of the initiating explosives is very large. During the initiating explosives production process, a large amount of toxic water containing mercury, lead, azo or phenols is emitted. If the waste water is not treated, it will cause serious environmental pollution. In addition, the transport of unpackaged initiating explosives is prohibited. Each detonator factory must set up its own explosives workshops, which leads to an increase in pollution sites and requires increased investment in environmental protection. Because of this, the existing detonator caps have safety problems during the manufacturing, transportation, storage and use processes. US Patent No. 3,978,791, issued September 1976, discloses a flying disc type detonator without initiating explosive. A low voltage and small current are passed through a small-diameter bridge wire to heat the bridge wire and trigger the detonation of the auxiliary propellant. The gas pressure generated by the deflagration cuts the central part of the metal disc and pushes it down along the cavity, it hits the delivered auxiliary charge at high speed, causing the delivered charge to detonate. The detonator has good security, but the process design is complicated and not suitable for industrial production. In recent years, the research of non-priming detonator has been highly appreciated by relevant departments at home and abroad and has become a remarkable and important topic. Many inventions in this field have been patented and some have received patent rights. The common feature of these disclosed primerless detonators is that they use a high explosive or a low sensitivity preparation instead of primers, thereby greatly improving safety. However, due to the complex structure of these blasting caps, complicated processing technology, great difficulty and high product cost of these blasting caps, the development of blasting caps without initiating explosive is restricted.

SUMMARY OF THE PRESENT INVENTION In order to solve the problems of insecurity of the detonator with the initiating explosive and high cost of the detonator without an initiating explosive, the present invention provides a micro initiating explosive for the detonating cap. The specific technical solution is as follows: a micro initiating explosive for the detonator contains more than one high explosive and more than one initiating explosive; wherein the weight ratio of the high explosive is as follows: Hexogen 10-50, PETN 10-70; and wherein the weight ratio of the initiating explosive is: dinitrodiazophenol 45-85, lead azide 25-60, lead trinitroresorcinol 2-10, nickel hydrazine nitrate 55-75, cadmium perchlorate tricarbohydrazide 55-75, and wherein more than one high explosive and more than one initiating explosive are uniformly mixed .

A micro-initiating agent for the detonator contains more than one high explosive and more than one initiating explosive, and it can further use a surfactant sodium dodecylbenzenesulfonate of 0.05-0.5 and more than one binder;

and wherein the weight ratio of the high explosive is: Hexogen 10-50, PETN 10-70; and wherein the weight ratio of the initiating explosive is as follows: dinitrodiazophenol 45-85,

lead azide 25-60, lead trinitroresorcinol 2-10, nickel hydrazine nitrate 55-75, cadmium perchlorate tricarbohydrazide 55-75; and wherein the weight ratio of the binder is as follows:

Carboxymethyl cellulose 1.5-1.8, nitrocellulose 1.0-5.0, dextrin 1.0-5.0, gelatin 1.0-5.0, shellac 1.0-5.0,

Peach Gum 1.0-5.0. When the micro initiating explosive is prepared by direct charging or a physical mixing method, one or two of the high explosives mentioned above are mixed with one or two of the initiating explosives.

In order to improve the dispersibility of the micro-initial explosive and make it easy to fill

25, the charge of the detonator of the present invention may further utilize a binder and a surfactant, the binder used including natural binders such as carboxymethyl cellulose, dextrin, gelatin, shellac, peach gum, bone glue, and synthetic binders such as nitrocellulose, polyvinyl alcohol,

zinc stearate and butyral. Among them, carboxymethyl cellulose, shellac, polyvinyl alcohol and nitrocellulose are best. In general, the consumption amount of the binder should be 1-10% of the amount of micro-initiating explosive. The usage amount of the surfactant such as sodium dodecylbenzene sulfonate is 50.1-3% of the usage amount of the binder. More than one high explosive, more than one initiating explosive, the surfactant and more than one binder will be mixed and used. The present invention has the following advantages: the detonator with the micro-initiating explosive according to the present invention has the advantages of simple structure, high operational reliability, short exposure time, good ignition consistency and stable detonation performance, and a micro-initiating explosive is mainly used to make the current explosive to replace, in the case of the micro-initiating explosive, the high explosive and the initiating explosive can be filled directly, or they can be made into a micro-initiating explosive with good dispersibility, and the factory can use the conventional production technology and equipment of the detonator without changing the existing production lines, the advantage is that compared to conventional detonators, the charge quantity of the initiating explosive can be reduced by 30-60% and the cost compared to current detonators by 20-30% can be reduced, and the emission of waste water and toxic gas products is reduced, which achieves the effect of environmental protection; in addition, the safety of assembling the detonator is improved, and the explosive power and flame sensitivity are guaranteed, while the sensitivity to static electricity, friction, shock, light and heat is reduced, thereby ensuring the safety of the detonator during the manufacturing, transportation, storage and use process is improved; moreover, the total charge amount of the detonator can be reduced and the dispersibility of the preparation can be improved.

DETAILED DESCRIPTION The present invention is explained in more detail below in connection with exemplary embodiments.

Embodiment 1 A micro-initiating explosive for the detonator contains the raw materials in the following weight ratio: hexogen (C3H6N6O6) 30 g, 5 dinitrodiazophenol (DDNP) 70 g, the above-mentioned raw materials are mixed uniformly. Example 2 A micro-initial explosive for the detonator contains the raw materials in the following weight ratio: hexogen (C3H6N606) 25 g, dinitrodiazophenol (DDNP) 75 g, the dinitrodiazophenol is applied to the hexogen raw material and mixed uniformly. Embodiment 3 A micro-initiating explosive for the detonator contains the raw materials in the following weight ratio: PETN (CSH8N4012) 50 g, dinitrodiazophenol (DDNP) 50 g, the above-mentioned raw materials are mixed uniformly.

Embodiment 4 A micro-initial explosive for the detonator contains the raw materials in the following weight ratio: hexogen (C3H6N606) 20 g, PETN (C5H8N4012) 10 g, dinitrodiazophenol (DDNP) 70 g, the above-mentioned raw materials are mixed uniformly. Example 5

A micro-initial explosive for the detonator contains the raw materials in the following weight ratio: hexogen (C3H6N606) 30 g, dinitrodiazophenol (DDNP) 60 g, lead trinitroresorcinol 10 g, the above raw materials are mixed uniformly.

Embodiment 6 A micro-initial explosive for the detonator contains the raw materials in the following weight ratio: PETN (C5H8N4012) 50 g, dinitrodiazophenol (DDNP) 45 g, lead trinitroresorcinol 5 g, the above-mentioned raw materials are mixed uniformly. Example 7 A micro-initiating explosive for the detonator contains the raw materials in the following weight ratio: hexogen (C3H6N6O6) 40 g, lead azide 60 g, the above-mentioned raw materials are mixed uniformly. Embodiment 8 A micro-initiating explosive for the detonator contains the raw materials in the following weight ratio: PETN (C5H8N4012) 60 g, lead azide 40 g, the above-mentioned raw materials are mixed uniformly.

Exemplary embodiment 9 A micro-initial explosive for the detonator contains the raw materials in the following weight ratio:

Hexogen (C3H6N606) 50g, lead azide 40g, lead trinitroresorcinol 10g, the above raw materials are mixed uniformly.

Example 10

A micro-initial explosive for the detonator contains the raw materials in the following weight ratio: PETN (C5H8N4012) 70 g, lead azide 25 g, lead trinitroresorcinol 5 g,

the raw materials mentioned above are mixed uniformly.

Exemplary embodiment 11 A micro-initial explosive for the detonator contains the raw materials in the following weight ratio: hexogen (C3H6N606) 25 g,

Nickel hydrazine nitrate ((NHN) 75g, the above raw materials are mixed uniformly.

Exemplary embodiment 12 A micro-initial explosive for the detonator contains the raw materials in the following weight ratio:

Hexogen (C3H6N6O6) 20 g, nickel hydrazine nitrate (NHN) 70 g, lead trinitroresorcinol 10 g, the above raw materials are mixed uniformly.

Example 13

Fin micro-initial explosive for the detonator contains the raw materials in the following weight ratio:

Hexogen (C3H6N606) 25g, cadmium perchlorate tricarbohydrazide (GTG) 75g, the above raw materials are mixed uniformly. Embodiment 14 5A micro-initiating explosive for the detonator contains the raw materials in the following weight ratio: PETN (CSH8N4012) 35 g, cadmium perchlorattricarbohydrazide (GTG) 65 g, the above-mentioned raw materials are mixed uniformly.

Embodiment 15 A micro-initial explosive for the detonator contains the raw materials in the following weight ratio: hexogen (C3H6N606) 15 g, dinitrodiazophenol (DDNP) 85 g, The dinitrodiazophenol is coated on the raw material of hexogen and treated with surfactant sodium dodecylbenzenesulfonate (0.05) and binder carboxymethyl cellulose ( 1.50) are granulated, then they are evenly mixed.

Working Example 16 A micro-initial explosive for detonator contains the raw materials in the following weight ratio: PETN (C5H8N4012) 40 g, dinitrodiazophenol (DDNP) 60 g, The dinitrodiazophenol is coated on the raw material of Hexogen and treated with 0.1 g sodium dodecylbenzenesulfonate surfactant and 2.0 g Binding agent dextrin granulated, then they are evenly mixed.

Example 17

A micro-initial explosive for detonator contains the raw materials in the following weight ratio: PETN (C5H8N4012) 40g, Nickel hydrazine nitrate (NHN) 55g, Lead trinitroresorcinol 5g, The nickel hydrazine nitrate and lead trinitroresorcinol are applied on the raw material of PETN, and treated with 0.5g surfactant sodium dodecylbenzene sulfonate and 2.0 g binder gelatin granulated, then they are mixed evenly. Example 18 A micro-initial explosive for the detonator contains the raw materials in the following weight ratio: PETN (C5H8N4012) 3g, lead azide 40g, cadmium perchlorattricarbohydrazide (GTG) 70g, The cadmium perchlorattricarbohydrazide (GTG) 70g The cadmium perchlorattricarbohydrazide is applied to the raw material of PETN and lead azide and with 0.08 g surfactant sodium dodecylbenzenesulfonate and 3.0 g binder shellac granulated, then they are mixed evenly. Example 19 A micro-initial explosive for the detonator contains the raw materials in the following weight ratio: hexogen (C3H6N606) 28 g, cadmium perchlorate tricarbohydrazide (GTG) 70 g, lead trinitroresorcinol 2 g, the cadmium perchlorate tricarbohydrazide and lead trinitroresorcinol are applied to hexogen and treated with 0.15 g surfactant sodium dodecylbenzene sulfonate and 1 .0 g binder peach gum granulated, then they are mixed evenly.

Exemplary embodiment 20 A micro-initial explosive for the detonator contains the raw materials in the following weight ratio: PETN(C5H8N4012) 40 g,

Cadmium perchlorate tricarbohydrazide (GTG) 55g, lead trinitroresorcinol 5g, The cadmium perchlorate tricarbohydrazide and lead trinitroresorcinol are applied on the raw material of PETN, and granulated with 0.10g surfactant sodium dodecylbenzenesulfonate and 1.5g binder nitrocellulose, then they are mixed evenly.

Example 21 A micro-initial explosive for the detonator contains the raw materials in the following weight ratio: hexogen (C3H6N606) 10 g, PETN (C5H8N4012) 25 g, cadmium perchlorattricarbohydrazide (GTG) 55 g, lead trinitroresorcinol 10 g, the cadmium perchlorattricarbohydrazide and lead trinitroresorcinol are applied to the raw material of hexogen and PETN applied and granulated with 0.09 g surfactant sodium dodecylbenzenesulfonate and 1.80 g binder carboxymethyl cellulose, then they are mixed uniformly.

(Dinitrodiazophenol) DDNP and (PETN) PETN : PETN is not less than 25% and not more than 75%, DDNP and (Hexogen) RDX : RDX is not less than 10% and not more than 45%.

The process of chemical co-precipitation to produce the micro-initiating explosive is mainly to add the high explosive in the synthesis and manufacturing process of the initiating explosive to produce a micro-initiating explosive.

Working Example 22 The micro-initiating agent for the detonator may consist of charging PETN and dinitrodiazophenol into the detonating cap one by one to make an industrial detonator No. 8, changing the originally initiating explosive-filled part of each detonating cap so that 0.15 g PETN and then 0.18g of dinitrodiazophenol are loaded, namely PETN (CSH8N4012)0.15g, dinitrodiazophenol 0.18g, by assembling a reinforcing cap, a semi-finished blasting cap for producing various finished blasting caps can be prepared.

Claims (2)

patent claims 1. Micro initiating explosive for the detonator, characterized in that it contains a high explosive and more than one initiating explosive; wherein the weight ratio of the high explosive is as follows: Hexogen 10-50, PETN 10-70; wherein the weight ratio of the initiating explosive is as follows: dinitrodiazophenol 45-85, lead azide 25-60, lead trinitroresorcinol 2-10, nickel hydrazine nitrate 55-75, cadmium perchlorate tricarbohydrazide 55-75; and wherein the high explosive and more than one initiating explosive are mixed and used. 2. Micro initiating explosive for the detonator according to claim 1, characterized in that it contains initiating explosive as a high explosive and more than one emission control unit; further containing a surfactant sodium dodecylbenzene sulfonate from 0.05-0.5 and more as a binder; and wherein the weight ratio of the high explosive is: Hexogen 10-50, PETN 10-70; wherein the weight ratio of the initiating explosive is as follows: dinitrodiazophenol 45-85, lead azide 25-60, lead trinitroresorcinol 2-10, nickel hydrazine nitrate 55-75, cadmium perchlorate tricarbohydrazide 55-75; and wherein the weight ratio of the binder is as follows: carboxymethylcellulose, 1.5-1.8, nitrocellulose, 1.0-5.0, dextrin, 1.0-5.0, gelatin 1.0-5.0, shellac 1.0-5.0, peach gum 1.0-5.0; and wherein the high explosive, more than one initiating explosive, the surfactant and more than one binder are mixed and used.