RU2147365C1 - Detonating device - Google Patents

Abstract

FIELD: means of initiation of explosive charges with a preset time delay. SUBSTANCE: in the known detonating device containing arranged in succession in the casing: a compacted detonating explosive charge; a detonating explosive charge with bulk density; an initiating explosive charge and an ignition assembly, the latter is made in the form of a metal spiral connected to an electronic module consisting of a detonating unit connected to a two-wire line shunted by protective diodes D₁ and D₂ from the control center. Connected to the first storage capacitor C₁ that is connected to the first input of microprocessor with a crystal oscillator. Connected to the second output of the detonating unit is the second storage capacitor C₂, connected to the series-connected ignition assembly and key K₁, whose point of connection via divider R₁, R₂ is connected to input 3 of the microprocessor, additionally connected to capacitor C₂ is the second key K₂, and the control inputs of both keys are connected to the first and second inputs of the microprocessor, the microprocessor has an individual identification number programmed at manufacture. EFFECT: explosion precise in time and remote check-up of detonator serviceability. 2 dwg

Description

 The invention relates to the development of means for initiating explosive charges (BB) with a specified time delay.

 Known detonating devices containing a housing in which the charges of the blasting and initiating explosives are placed, and the delay in blasting is achieved by the introduction of diaphragms of various designs, retarding substances, etc. [1,2].

 The capabilities of such devices are very limited and do not provide an accurate time delay when blasting.

 The objective of the present invention is to provide a programmable detonating device that would allow for accurate time-based blasting and remote testing of the detonator.

The essence of the invention lies in the fact that in the known detonating device containing located in series in the case the charge of the pressed blasting explosive; charge of blasting explosive with bulk density; the charge of the initiating explosive and the ignition unit (HC), the latter is made in the form of a metal spiral connected to an electronic module consisting of a detecting unit (DB) connected to a two-wire line shunted by protective diodes D ₁ and D ₂ from the control center (CC), the first storage capacitance C ₁ is connected to the first output of the database, which is connected to the first input of the microprocessor (MP) with a crystal oscillator, also connected to input two through a common connection point of the diodes D ₁ and D ₂ to the two-wire line. To the second output database connected second storage capacitance C ₂ connected with series hydrocarbon and the key K _1, the connection point of which via divider R ₁ R ₂ connected to input 3 MP to capacitance C ₂ is connected further second key K _2, and the control inputs both keys are connected to the first and second outputs of the MP, and the MP has an individual identification number programmed during manufacture.

 A description of the device is illustrated in FIG. 1 and 2.

 In FIG. 1 is indicated: 1 - case, 2 - charge of pressed blasting explosive; 3 - blasting explosive of bulk density; 4 - initiating explosive; 5 - ignition unit; 6 - electronic module; 7 - conclusions of the electronic module.

 In FIG. 2 is indicated: DB - detection unit; MP - microprocessor module; Q is a crystal oscillator; HC - ignition unit.

 The device operates as follows.

A two-wire line from the control center to the DB detection unit receives a sequence of bipolar pulses. In the database, pulses of positive polarity are rectified and charge the capacitance C ₁ to the operating voltage of the microprocessor (MP), this voltage is supplied to the power input input ₁ MP. Via the input ₂ MP from the line through the protective diodes D ₁ D _{2 is} programmed for the desired delay time. A quartz oscillator is used to accurately set the delay time. Next, the MP switches input ₂ to output ₃ mode and issues a control sequence of pulses to the line, which are read by the control unit to confirm the fixed delay time.

After the test is completed, negative polarity pulses are sent to the line. The database converts pulses of negative polarity from the line and charges the capacitance C ₂ through output ₂ . MP ₃ O switches in mode ₂ Rin and stored pending. When a coded sequence of pulses arriving along the line from the control unit at input ₂ MP, carrying the command "detonate", MP through output ₁ with the delay time set earlier, opens the key K ₁ and the energy stored in C ₂ is released on the spirals of the ignition unit initiating the detonating explosion devices.

If you need to quickly cancel the explosion, the key K _{2 is} turned _on and discharges the storage capacity C ₂ . In addition, after a predetermined time after the termination of the supply of pulses to the line, the storage capacity C _{2 is} automatically discharged through the divider R ₁ R ₂ .

 The use of the proposed devices allows the formation of explosive systems in which the detonation of charges can be carried out in any sequence and any group configuration, and to check the operability of the system at all stages of the preparation and conduct of the explosion.

List of references
1. A.S. N 1494671, CL F 42 B 3/04.

 2. Application for invention N 96100393/02, the decision to grant a patent dated 05/26/97, class. F 42 B 3/10, F 42 C 19/08.

Claims (1)

 A detonating device comprising a housing and a successively placed charge of a pressed blasting substance, a charge of a blasting substance of bulk density, a charge of an initiating substance and an ignition unit, characterized in that the ignition unit is made in the form of a metal spiral connected to an electronic module consisting of a detection unit, connected to a two-wire line, shunted by the first and second diodes from the central device, to the first output of the detection unit is connected the first a storage tank, which is connected to the first input of the microprocessor with a quartz generator, also connected to the second input from the connection of the first and second diodes to a two-wire line, to the second output of the detection unit, a second storage tank connected to the ignition unit and the first key connected in series, the connection point of which connected through a divider to the third input of the microprocessor, an additional second key is connected to the second capacitance, and the control inputs of both keys are connected the first and second outputs of the microprocessor, wherein the microprocessor has a unique identification number that is programmed during production.

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