RU75731U1 - ELECTRODETONIC SYSTEM - Google Patents

Abstract

The utility model relates to electronic detonation systems and is intended for high-precision initiation of explosive charges during blasting.

The technical result of the claimed utility model is to simplify the design of the electric detonation system while maintaining the properties of time-accurate blasting and remote testing of the detonators. The claimed technical result is achieved due to the fact that the electric detonation system containing at least one electric detonator made of a housing (sleeve) in which an electric igniter, explosive, tube, electronic explosion delay unit containing a capacitor and a microprocessor having an individual identification number are placed, programmed during manufacture, characterized in that the plug is placed in the electric detonator in front of the electronic delay assembly, through which to the electronic assembly two wires are connected from the blast line, which is connected to the two-wire end of the computer peripheral adapter, the other end of which is connected via USB to the computer.

Description

Application area

The utility model relates to electronic detonation systems and is intended for high-precision initiation of explosive charges during blasting.

State of the art

Known from the prior art are detonators (see [1]) of the ED type, consisting of a detonator capsule, nitro-lacquer, an incendiary or inert composition, an igniter composition, an incandescent bridge, a wire, and a plastic plug.

The disadvantage of these detonators is their low accuracy, since they are used without a chip that allows the initiation of explosives from a computer.

Known igniter device [2] for initiating detonators, which contain at least one main charge in the detonator housing, containing an electric igniter head, a current source connected to an electric igniter head, and an electronic unit including a signal decoding means configured to receive a start signal, supplied to the igniter through an external signal conductor, a delay circuit for supplying an ignition signal after a predetermined period of time follows the reception of the start signal, switching means for receiving the signal after the power source compound elektrovosplamenitelnoy ignition head secured triggering the latter and at least one semiconductor chip IC.

In the known igniter device, the possibility of reducing the duration of the operation of the igniter caps is limited by the capacity of the current source. The miniaturization of electronics, which is desirable in itself, increases sensitivity to static electricity and other disturbances, which, as part of blasting technology, pose a safety concern. Mechanical

the sensitivity of electronic parts also creates difficulties in the final assembly of the detonator and, in particular, in the search for possibilities of simple articulation of finished parts at the work site.

The closest analogue is a detonating device [3], comprising a housing and a successive 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 a 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 block a first storage capacitor connected to the first input of the microprocessor with a crystal oscillator, also connected to the second input from the connection of the first and second diodes to a two-wire line, a second storage capacitor connected to the ignition unit and the first key connected in series to the second output of the detection unit the connection point of which through the divider is connected to the third input of the microprocessor, an additional second key is connected to the second capacity, and ulation key inputs both connected to the first and second outputs of the microprocessor, wherein the microprocessor has a unique identification number that is programmed during production.

The detonator allows for accurate time-based blasting and remote verification of the detonator’s performance.

The disadvantage of this device is its manufacturing complexity and the multiplicity of connections to the microprocessor. As a result, such a detonator is expensive.

The technical result of the claimed utility model is to simplify the design of the electric detonation system while maintaining the properties of time-accurate blasting and remote testing of the detonators.

Brief Description of the Drawings

Figure 1 shows the structural device of the electric detonation system, where 1 is the housing (sleeve) of the electric detonator, 2 is a plug, 3 is an electronic unit for delaying blasting, 4 is an electric igniter, 5 is an explosive, 6 is an output wire, 6 is an output wire, 7 is a capacitor, 8 is microprocessor, 9 - blast line, 10 - computer peripheral adapter, 11 - USB port, 12 - computer.

Device essence

The claimed technical result is achieved due to the fact that the electric detonation system (see Figure 1), containing at least one electric detonator made of a housing (sleeve) (1), in which an electric igniter (4), an explosive (5), a tube (2), an electronic explosion delay unit (3), comprising a capacitor (7) and a microprocessor (8) having an individual identification number programmed during manufacture, characterized in that the plug (2) is placed in the electric detonator in front of the electronic delay unit (3) , across which is connected to the electronic node two wires (6) from the blast line (9), which is connected to the two-wire end of the peripheral adapter (10) of the computer, the other end of which is connected via the USB port (11) to the computer (12). The electric igniter (4) is connected to the electronic unit (3) and is located in the housing (sleeve) (1) between the electronic unit (3) and the explosive (5) so that it contacts the latter.

The plug (2) is used to seal the electronic delay unit (3). Simplification of the design is ensured by eliminating the need for diodes and installing connections to them, as well as eliminating the need for several storage capacities.

The system operates as follows.

The blast line is wired at the blast site and the inlet end of the line is retracted for safe removal. The electric detonator (s) with wires (6) are connected to the blast line (9).

To test the detonator operability via a two-wire line (9) from a computer (12), a signal is supplied through the peripheral adapter (10) to the line, which is fed through the wires (6) to the electronic delay unit (3), where the microprocessor (8)

initiates it as a charge and supplies power to the capacitor (7) of the electric detonator. In this case, the capacitor (7) of the electric detonator is charged.

A two-wire blast line (9) is used both to supply power to the electronic detonator and to transmit encoded commands to detonators from a computer (12) and to obtain response information from electric detonators.

Checking the operability of detonators is determined by the feedback signals received from the response information from the electric detonators, which can be used to check the voltage of each capacitor (which should not be less than 12V). The signals of a sequence of bipolar pulses from electric detonators are fed to a computer, where the detection degree of the motherboard records the degree of charge. This action is similar to the process of determining the degree of charge of a laptop battery and is software implemented in any operating system, for example. Windows XP

Pulses of positive polarity are rectified and charge the capacitance of the capacitor to the operating voltage of the microprocessor in the electronic delay unit (3). This voltage is applied to the microprocessor's power input.

Since the electronic delay unit (3) is a microcircuit having a microprocessor (8) with its individual identification number programmed during the production of the electric detonator, it is possible to determine the degree of charging of each electric detonator in a common line (9). Thanks to the individual number, the operator can access each electric detonator independently.

The registration of an individual identification number in the integrated circuit of the electronic delay unit (3) is carried out in a standard way during personalization on specialized equipment. Personalization is a fully automated process that does not require staff intervention. The process of personalizing an integrated circuit is a record of personal data, including an identification number for its further storage and reading.

The degree of charge of each capacitor (7) of the system detonator is displayed on the computer.

The use of the system for detonation is carried out by pre-sending from the computer to the electric detonators in the signal line to program the explosion delay time, which is recorded in the chip timer of the electronic delay unit (3).

Via the microprocessor (8) of the electronic delay unit (3), the desired delay time is programmed from the computer (12). As a timer for fine-tuning the delay time, for example, a quartz oscillator can be used. Undermining is performed by submitting a special command from the computer, which switches the microprocessor to the output mode from the main power supply and switches to stand-alone by issuing a control sequence of pulses that are read from the computer to confirm the fixed delay time. With the transition of the electric detonator to stand-alone power supply, the timer of the electronic delay unit chip (3) counts the programmed time and is triggered even if the blast line (9) is destroyed by this moment. At the time of the explosion from the capacitor (7), an electric current is supplied to the electric igniter (4), and it ignites the explosive (5). An explosion occurs.

Using the proposed system, despite its simplicity, allows you to create explosive systems in which the detonation of charges can be carried out in any sequence and any group configuration, and to verify the system’s performance at all stages of the preparation and conduct of the explosion.

Information sources:

1. GOST 9089-75

2. Patent DE 3533389, F42C 11/06

3. Patent RU 2147365, F42B 3/10, F42C 19/08

Claims (1)

An electric detonation system comprising at least one electric detonator made of a housing (sleeve) in which an electric igniter, an explosive, a plug, an electronic detonation delay assembly comprising a capacitor and a microprocessor having an individual identification number programmed during manufacture are located, characterized in that the plug placed in the electric detonator in front of the electronic delay unit, through which two wires are connected to the electronic node from the blast line, which is connected to the two-wire end of the computer peripheral adapter, the other end of which is connected via a USB port to the computer.