CN211552624U - High-energy capacitor energy-storage plasma igniter digital electric detonator - Google Patents

Abstract

The utility model relates to a high-energy capacitor energy storage plasma igniter digital electric primer, belonging to the technical field of high-energy capacitor energy storage plasma igniter digital electric primer; the technical problem to be solved is as follows: the improvement of the digital electric detonator structure of the high-energy capacitor energy-storage plasma igniter is provided; the technical scheme for solving the technical problem is as follows: the detonator is characterized by comprising a plastic shell, wherein an explosive sealing cover is arranged at one end of the plastic shell, an igniter sealing head is arranged at the other end of the plastic shell, the igniter sealing head is of a hollow screw structure, an insulated wire is led out from one end of the igniter sealing head, the other end of the igniter sealing head is inserted into the plastic shell and is fixedly connected with the plastic shell through threads, and main explosives are filled in a shell of the plastic shell; the detonator end socket is connected with the signal output end of the capacitive energy storage device through an insulated wire, and the signal input end of the capacitive energy storage device is connected with the network digital detonator through a network leg wire; the utility model discloses be applied to initiating tool.

Description

High-energy capacitor energy-storage plasma igniter digital electric detonator

Technical Field

The utility model relates to a high energy electric capacity energy storage plasma igniter digital electric detonator belongs to high energy electric capacity energy storage plasma igniter digital electric detonator technical field.

Background

The existing detonator used in the civil explosive industry can detonate the detonator only by mounting a detonator, and is structurally shown in figure 1, and mainly comprises a shell, a powder injection core, main charge, detonating explosive, a detonator mounting hole, a wire guide hole, an energy gathering hole, a box cover, a partition plate, a cavity, a detonator anti-dropping device, a core gland and the like, wherein the main charge adopts mixed explosive with low sensitivity, the detonating explosive is insensitive Soxhlet gold explosive, the main charge and the detonating explosive are filled in a plastic shell of the detonator, the detonator is required to be mounted, the detonator is detonated through the detonating detonator, and then emulsion explosive is detonated through the detonator.

Because the inside of the existing industrial electric detonator, digital electronic detonator or detonating tube detonator is filled with the initiating explosive (such as nickel hydrazine nitrate or dinitrodiazophenol) with extremely high mechanical sensitivity, explosion safety accidents are easy to occur in the daily production, transportation, storage and use processes. In order to improve the safety of the civil blasting industry in the production, transportation, storage and blasting engineering operation of blasting equipment, the structure of the existing blasting device needs to be correspondingly improved.

SUMMERY OF THE UTILITY MODEL

The utility model discloses an overcome not enough that exists among the prior art, the technical problem that will solve is: provides an improvement of a digital electric detonator structure of a high-energy capacitance energy-storage plasma igniter.

In order to solve the technical problem, the utility model discloses a technical scheme be: a high-energy capacitance energy storage plasma igniter digital electric detonator comprises a plastic shell, wherein an explosive seal cover is arranged at one end of the plastic shell, an igniter seal head is arranged at the other end of the plastic shell, the igniter seal head is of a hollow screw structure, an insulated conducting wire is led out from one end of the igniter seal head, the other end of the igniter seal head is inserted into the plastic shell and is arranged, the igniter seal head is fixedly connected with the plastic shell through threads, and main explosives are filled in a shell of the plastic shell;

the detonator seal head is connected with the signal output end of the capacitive energy storage device through an insulated wire, and the signal input end of the capacitive energy storage device is connected with the network digital detonator through a network leg wire.

The plasma detonator is characterized in that a control tube is arranged at one end of the detonator sealing head, the control tube and a steel sleeve are connected into a whole in a compression mode through a packaging clamping waist, a control circuit board is packaged inside the control tube, the control circuit board is connected with a plasma igniter through an ignition lead, the plasma igniter is in contact with an initiating explosive, and the initiating explosive is in contact with an initiating explosive.

The plasma igniter is manufactured by adopting a printed circuit board process, a pair of conductive copper foils is arranged on two sides of the printed circuit board in parallel, an anode bonding pad A1 is arranged on one conductive copper foil, a cathode bonding pad B1 is arranged on the other conductive copper foil, a copper foil protrusion c and a copper foil protrusion d are arranged between the two conductive copper foils, the distance between the copper foil protrusion c and the copper foil protrusion d is less than 0.2 mm, a copper foil bridge line E is also arranged between the copper foil protrusion c and the copper foil protrusion d, the line width of the copper foil bridge line E is less than 75 microns, and the resistance value of the copper foil bridge line E approaches zero.

The plasma igniter is manufactured by adopting a printed circuit board process, a pair of conductive copper foils is arranged on two sides of the printed circuit board in parallel, an anode bonding pad A1 is arranged on one conductive copper foil, a cathode bonding pad B1 is arranged on the other conductive copper foil, a patch type plasma discharge thin-film device H1 is welded between the two conductive copper foils, the inside of the discharge thin-film device H1 is composed of a conductive metal layer c and a conductive metal layer d, the distance between the conductive metal layer c and the conductive metal layer d is smaller than 0.2 mm, a metal line bridge foil E is further arranged between the conductive metal layer c and the conductive metal layer d, the line width of the metal line bridge foil E is smaller than 75 microns, and the resistance value of the metal line bridge foil E is close to zero.

The capacitor energy storage device comprises a diode bridge Z1, a voltage dependent resistor Rw, a diode D1, a resistor R1, a high impedance resistor R0, a high voltage capacitor Cg and a current limiting fuse FB, and the circuit structure of the capacitor energy storage device is as follows:

the input end of the diode bridge Z1 is connected with the network digital initiator through a network pin wire, and the energy storage loop formed by the piezoresistor Rw, the diode D1, the resistor R1, the high-impedance resistor R0 and the high-voltage capacitor Cg is connected in parallel with the two ends of the output end of the diode bridge Z1.

The control circuit board is provided with a microprocessor IC1, a current amplifier IC2, a triode T1-T7, a diode D2-D3, a voltage stabilizing diode W1, a MOSFET switch tube NM, a resistor R2-R15 and an active capacitor C1, and the peripheral circuit structure of the microprocessor IC1 is as follows:

a pin 1 of the microprocessor IC1 is connected with one end of a resistor R8 in parallel and then is connected with a collector of a triode T5;

the pin 4 of the microprocessor IC1 is connected with one end of a resistor R11, the other end of a resistor R8, an emitter of a triode T4, an emitter of a triode T3 and the anode of an electrode capacitor C1, and the emitter of a triode T2 is connected with the 3.3V power input end;

the base of the triode T5 is connected with one end of a resistor R9 in parallel and then connected with the collector of a triode T4, the base of the triode T4 is connected with the anode of a diode D2, the cathode of the diode D2 is connected with one end of a resistor R7 in parallel and then connected with one end of a resistor R6, the collector of the triode T2 is connected with one end of a resistor R4, and the base of the triode T2 is connected with one end of a resistor R5 in parallel and then connected with the cathode of a zener diode W1;

the other end of the resistor R4 is connected with the other end of the resistor R5 in parallel, the other end of the resistor R6 and the emitter of the triode T1 are connected with the pin 1 of the current amplifier IC 2;

the pin 3 of the current amplifier IC2 is connected with the collector of a triode T3;

the collector of the triode T1 is connected with one end of the resistor R2 in parallel and then connected with the positive electrode output end of the capacitive energy storage device, and the base of the triode T1 is connected with the other end of the resistor R2 in parallel and then connected with one end of the resistor R3;

a pin 5 of the microprocessor IC1 is connected with the other end of the resistor R11 in parallel and then connected with one end of a resistor R12, the other end of the resistor R12 is connected with one end of a resistor R13 in parallel and then connected with the base of a triode T6, the collector of the triode T6 is connected with the base of a triode T7, the emitter of the triode T7 is connected with one end of a resistor R15, the collector of the triode T7 is connected with one end of a resistor R14 in parallel and then connected with the gate of a switch tube NM, the source of the switch tube NM is connected with the negative electrode of a diode D3 in parallel and then connected with the positive input end of the plasma igniter, and the drain of the switch tube NM is connected with the other end of a resistor R15 in parallel and then connected with;

the pin 7 of the microprocessor IC1 is connected with the anode of a diode D3;

the pin 8 of the microprocessor IC1 is connected with a resistor R10 in series and then is connected with the base electrode of a triode T3;

the negative electrode input end of the plasma igniter is sequentially connected with the other end of the resistor R14, the emitting electrode of the triode T6, the other end of the resistor R13, the pin 2 of the microprocessor IC1, the emitting electrode of the triode T5, the other end of the resistor R9, the negative electrode of the electrode capacitor C1, the positive electrode of the voltage stabilizing diode W1, the other end of the resistor R7, the pin 2 of the current amplifier IC2, and the other end of the resistor R3 is connected with the negative electrode output end of the capacitor energy storage device.

The control circuit board is provided with a MOSFET switch tube NM1, a resistor R22, a resistor R23 and a capacitor C21, and the peripheral circuit structure of the MOSFET switch tube NM1 is as follows:

the source electrode of the MOSFET switching tube NM1 is connected with the positive electrode input end of the plasma igniter;

the drain electrode of the MOSFET switching tube NM1 is connected with the anode output end of the capacitive energy storage device;

the grid of the MOSFET switching tube NM1 is connected with one end of a resistor R23 in parallel, one end of a capacitor C21 is connected with one end of a resistor R22, and the other end of the resistor R22 is connected with an SIN port of the capacitor energy storage device;

the other end of the resistor R23 is connected with the negative input end of the plasma igniter in parallel, and the other end of the capacitor C21 is connected with the negative output end of the capacitor energy storage device.

The model of the microprocessor IC1 is ES7P001 FGSA;

the current amplifier IC2 is model RLR 763.

The utility model discloses beneficial effect for prior art possesses does: the utility model provides a need not install the digital electron initiating explosive of high energy electric capacity energy storage plasma ignition utensil structure of detonator, electric capacity energy storage device through its connection is direct to carry out the high voltage instantaneously to the plasma ignition utensil, the heavy current discharges, main explosive detonates, simultaneously for guaranteeing engineering blasting network deployment, support the time delay control of discharging, be provided with special control circuit in addition in initiating explosive utensil, make whole device need not to install the detonator in addition, effectively improve production, transportation, storage, the security in the operation process, improve control accuracy and use reliability.

Drawings

The present invention will be further explained with reference to the accompanying drawings:

FIG. 1 is a schematic structural diagram of a conventional initiator;

FIG. 2 is a schematic structural view of the present invention;

fig. 3 is a schematic structural diagram of the detonator sealing head of the present invention;

FIG. 4 is a schematic structural view of the utility model in use;

FIG. 5 is a schematic structural view of the plasma igniter of the present invention;

fig. 6 is a schematic diagram of a control circuit according to embodiment 1 of the present invention;

fig. 7 is a schematic diagram of a control circuit according to embodiment 2 of the present invention;

in the figure: 10 is a plastic shell, 20 is an explosive cover, 30 is an igniter seal head, 40 is an insulated conducting wire, 50 is main explosive, 60 is a capacitive energy storage device, 70 is a network pin wire, 301 is a control tube, 302 is a packaging clamping waist, 303 is a steel sleeve, 304 is a control circuit board, 305 is an ignition lead, 306 is a plasma igniter, 307 is an initiating explosive, and 308 is an initiating explosive.

Detailed Description

The utility model relates to a digital electric initiating device of high energy electric capacity energy storage plasma igniter, including plastic housing (10), the one end of plastic housing (10) is provided with explosive closing cap (20), the other end of plastic housing (10) is provided with detonator head (30), detonator head (30) specifically is the hollow screw structure, insulated wire (40) is drawn forth to the one end of detonator head (30), the other end of detonator head (30) inserts the inside setting of plastic housing (10), detonator head (30) passes through threaded connection with plastic housing (10) and fixes, the shell intussuseption of plastic housing (10) is filled with main explosive (50);

the detonator seal head (30) is connected with a signal output end of the capacitive energy storage device (60) through an insulated wire (40), and a signal input end of the capacitive energy storage device (60) is connected with the network digital detonator through a network pin wire (70).

One end of the detonator sealing head (30) is provided with a control tube (301), the control tube (301) is connected with a steel sleeve (303) in a pressing mode into a whole through a packaging clamping waist (302), a control circuit board (304) is packaged in the control tube (301), the control circuit board (304) is connected with a plasma ignition tool (306) through an ignition lead (305), the plasma ignition tool (306) is in contact with an initiating explosive (307), and the initiating explosive (307) is in contact with a initiating explosive (308).

The plasma igniter (306) is manufactured by adopting a printed circuit board process, a pair of conductive copper foils is arranged on two sides of the printed circuit board in parallel, an anode bonding pad A1 is arranged on one conductive copper foil, a cathode bonding pad B1 is arranged on the other conductive copper foil, a copper foil bulge c and a copper foil bulge d are arranged between the two conductive copper foils, the distance between the copper foil bulge c and the copper foil bulge d is less than 0.2 mm, a copper foil bridge line E is also arranged between the copper foil bulge c and the copper foil bulge d, the line width of the copper foil bridge line E is less than 75 microns, and the resistance value of the copper foil bridge line E approaches zero.

The plasma igniter (306) is manufactured by adopting a printed circuit board process, a pair of conductive copper foils is arranged on two sides of the printed circuit board in parallel, an anode pad A1 is arranged on one conductive copper foil, a cathode pad B1 is arranged on the other conductive copper foil, a patch type plasma discharge thin-film device H1 is welded between the two conductive copper foils, the inside of the discharge thin-film device H1 is composed of a conductive metal layer c and a conductive metal layer d, the distance between the conductive metal layer c and the conductive metal layer d is smaller than 0.2 mm, a metal line bridge foil E is further arranged between the conductive metal layer c and the conductive metal layer d, the line width of the metal line bridge foil E is smaller than 75 microns, and the resistance value of the metal line bridge foil E approaches zero.

The capacitor energy storage device (60) comprises a diode bridge Z1, a voltage dependent resistor Rw, a diode D1, a resistor R1, a high impedance resistor R0, a high voltage capacitor Cg and a current limiting fuse FB, and the circuit structure of the capacitor energy storage device (60) is as follows:

the input end of the diode bridge Z1 is connected with the network digital initiator through a network pin wire (70), and the energy storage loop formed by the piezoresistor Rw, the diode D1, the resistor R1, the high-impedance resistor R0 and the high-voltage capacitor Cg is connected in parallel with the two ends of the output end of the diode bridge Z1.

The control circuit board (304) is provided with a microprocessor IC1, a current amplifier IC2, a triode T1-T7, a diode D2-D3, a voltage stabilizing diode W1, a MOSFET switch tube NM, a resistor R2-R15 and an active capacitor C1, and the peripheral circuit structure of the microprocessor IC1 is as follows:

a pin 1 of the microprocessor IC1 is connected with one end of a resistor R8 in parallel and then is connected with a collector of a triode T5;

the pin 4 of the microprocessor IC1 is connected with one end of a resistor R11, the other end of a resistor R8, an emitter of a triode T4, an emitter of a triode T3 and the anode of an electrode capacitor C1, and the emitter of a triode T2 is connected with the 3.3V power input end;

the base of the triode T5 is connected with one end of a resistor R9 in parallel and then connected with the collector of a triode T4, the base of the triode T4 is connected with the anode of a diode D2, the cathode of the diode D2 is connected with one end of a resistor R7 in parallel and then connected with one end of a resistor R6, the collector of the triode T2 is connected with one end of a resistor R4, and the base of the triode T2 is connected with one end of a resistor R5 in parallel and then connected with the cathode of a zener diode W1;

the other end of the resistor R4 is connected with the other end of the resistor R5 in parallel, the other end of the resistor R6 and the emitter of the triode T1 are connected with the pin 1 of the current amplifier IC 2;

the pin 3 of the current amplifier IC2 is connected with the collector of a triode T3;

the collector of the triode T1 is connected with one end of a resistor R2 in parallel and then connected with the positive electrode output end of a capacitive energy storage device (60), and the base of the triode T1 is connected with the other end of a resistor R2 in parallel and then connected with one end of a resistor R3;

a pin 5 of the microprocessor IC1 is connected with the other end of the resistor R11 in parallel and then connected with one end of a resistor R12, the other end of the resistor R12 is connected with one end of a resistor R13 in parallel and then connected with the base of a triode T6, the collector of the triode T6 is connected with the base of a triode T7, the emitter of the triode T7 is connected with one end of a resistor R15, the collector of the triode T7 is connected with one end of a resistor R14 in parallel and then connected with the gate of a switch tube NM, the source of the switch tube NM is connected with the negative electrode of a diode D3 in parallel and then connected with the positive input end of the plasma ignition tool (306), and the drain of the switch tube NM is connected with the other end of a resistor R15 in parallel and then connected with the positive output;

the pin 7 of the microprocessor IC1 is connected with the anode of a diode D3;

the pin 8 of the microprocessor IC1 is connected with a resistor R10 in series and then is connected with the base electrode of a triode T3;

the negative electrode input end of the plasma igniter (306) is sequentially connected with the other end of the resistor R14, the emitting electrode of the triode T6, the other end of the resistor R13, the pin 2 of the microprocessor IC1, the emitting electrode of the triode T5, the other end of the resistor R9, the negative electrode of the polar capacitor C1, the positive electrode of the voltage stabilizing diode W1, the other end of the resistor R7, the pin 2 of the current amplifier IC2, and the other end of the resistor R3 is connected with the negative electrode output end of the capacitor energy storage device (60).

The control circuit board (304) is provided with a MOSFET switch tube NM1, a resistor R22, a resistor R23 and a capacitor C21, and the peripheral circuit structure of the MOSFET switch tube NM1 is as follows:

the source electrode of the MOSFET switching tube NM1 is connected with the positive electrode input end of the plasma igniter (306);

the drain electrode of the MOSFET switching tube NM1 is connected with the anode output end of the capacitive energy storage device (60);

the grid of the MOSFET switching tube NM1 is connected with one end of a resistor R23 in parallel, one end of a capacitor C21 is connected with one end of a resistor R22, and the other end of the resistor R22 is connected with an SIN port of a capacitor energy storage device (60);

the other end of the resistor R23 is connected in parallel with the negative input end of the plasma igniter (306), and the other end of the capacitor C21 is connected with the negative output end of the capacitor energy storage device (60).

The model of the microprocessor IC1 is ES7P001 FGSA;

the current amplifier IC2 is model RLR 763.

The utility model mainly aims at the electric energy stored by the high energy capacitor to instantaneously carry out high voltage and heavy current discharge between the plasma igniter electrodes, so that the plasma igniter central bridge foil forms a specially designed control discharge circuit and an igniter charge structure for igniting the igniter by punctiform high voltage and high temperature deflagration plasma gas shock waves; the electric energy stored by the high-energy capacitor is more than or equal to 0.5J;

the utility model discloses improve to current initiating explosive, adopt one kind can satisfy the electric energy that triggers, control high pressure energy storage electric capacity and discharge in plasma ignition utensil, instantaneously form high-pressure, the gaseous shock wave of high temperature plasma and detonate the high explosive in the initiating explosive, form the initiating explosive that need not to install the detonator and detonate.

As shown in fig. 2 and 3, specifically, the structure assembly diagram of the digital electronic initiator of the high-energy plasma igniter and the structure diagram of the detonator sealing head of the present invention can be correspondingly installed in the plastic shell through threads;

the initiating explosive arranged in the detonator seal head can be a hexogen explosive, and the main explosive can be a mixed explosive;

as shown in fig. 4, the structure diagram of the connection between the digital electronic detonator of the high-energy plasma igniter and the capacitor energy storage device is that the detonator provided by the utility model is connected with the signal output end of the capacitor energy storage circuit body through a high-strength coated insulated multi-core wire, and the signal input end of the capacitor energy storage device is connected with a network pin wire and connected with a corresponding control device; the shell of the capacitive energy storage device is made of waterproof plastic, and an energy storage circuit is packaged in the plastic package body; the detonating tool is connected with the capacitive energy storage device to form a group of detonating units; when the special setting is carried out, the diameter D of the plastic shell of the detonator is larger than 35mm, and the length L of the plastic shell of the detonator is larger than 100 mm.

As shown in fig. 5, a diagram a is a schematic structural diagram of a printed circuit board type plasma igniter, the plasma igniter provided by the utility model etches on the copper foil of the printed circuit board to form a bridge copper foil line with a micrometer magnitude line width of which the resistance approaches zero; in the figure, a black part is a circuit copper clad surface, A1 and B1 are positive and negative electrode pads, c and d are conductive copper foil bulges, and a bridge copper foil wire E with micrometer-order line width is arranged between the c and d conductive copper foil bulges; fig. B is a schematic diagram of a structure of a plasma igniter of H1 type welded on a printed circuit board, the plasma igniter provided by the utility model is formed by separating the printed circuit board and a discharge thin film device H1, the discharge thin film device H1 is a plasma discharge device, the plasma igniter forms a micrometer-order thin film circuit with a resistance approaching to zero by adopting vacuum sputtering metal film etching on an insulating board (ceramic chip or other insulating materials), wherein the thickness of the insulating board of the discharge thin film device H1 is less than 0.5mm, the width is less than 2.5mm, the height is less than 3mm, the plasma discharge device H1 is specifically welded on the black circuit copper foil covered surface of the printed circuit board, and the c and d conductive metal layers are respectively electrically connected with positive and negative electrode pads a1 and B1; the carrier for positive and negative electrode discharge of the discharge thin-film device H1 plasma igniter is a bridge metal wire E with a micrometer-order line width, and the resistance value of the bridge metal wire E is close to zero.

As shown in fig. 6 and 7, specifically do the utility model discloses two kinds of embodiments of control circuit in the initiating device, according to the in-service use demand, the utility model discloses a power supply and communication sharing bus adopt the low-voltage to be less than or equal to 20VDC to the jump power supply mode that the high-voltage is more than or equal to 60VDC and two wire system buses of communication sharing, make control circuit high pressure resistant, electric capacity energy storage height, anti-electromagnetic interference strong, the reliability is high, the safety and stability.

The control circuit of the two embodiments consists of a control circuit, a plasma igniter circuit and an energy storage circuit;

as shown in fig. 6, the control circuit in the first embodiment is composed of a microprocessor chip IC1, a current amplifier IC2, a MOSFET switch tube NM, a transistor T1-T7, a diode D2-D3, a voltage regulator tube W1, a resistor R2-R15, and a capacitor C1; the micro-processing chip IC1 can select 51 series 8-bit CPU special chips, or adopt ES7P001FGSA, EFM8SB1, STM8L05xx, MAX series and other general micro-processing chips; the IC2 current amplifier chip adopts RLR 763; the triode T3-T5, the resistors R6-R10 and the diode D2 form a voltage/current communication conversion circuit; the triode T6-T7, the MOSFET switch tube NM and the resistors R11-R15 form a driving switch circuit, and the electric energy stored by the high-voltage capacitor Cg is controlled by the internal program of the microprocessing chip IC1 to be discharged in the plasma igniter according to time sequence to form high-voltage and high-temperature plasma shock waves; the communication RX end of the microprocessor IC1 is connected with a triode T5, a triode T4, a resistor R8, a resistor R9, a diode D2, a resistor R6 and a resistor R7, and the triode T1 receives a voltage modulation information number of a power supply V + of the network digital initiator; the communication TX end of the microprocessor IC1 is connected with the RF end of the current amplifier chip RLR763 through a resistor R10 and a triode T3, and communicates with the network digital detonator through the current modulation of the current amplifier chip RLR763 on a power supply V +; the I/O end of the microprocessor IC1 is connected with the base electrode of the triode T6 through resistors R12 and R13, and a circuit consisting of the triode T6, T7, resistors R14 and R15 controls the D pole and the S pole of the MOSFET switch tube NM to be conducted when the high level of the G pole of the MOSFET switch tube NM is larger than 30V, so that the high-voltage capacitor Cg is discharged in the plasma igniter; the I/O terminal of the microprocessor IC1 is connected to the S terminal of the MOSFET switching tube NM through a diode D3, and the software of the microprocessor IC1 judges the high and low levels of the I/O terminal to check whether the plasma igniter is open-circuited or damaged.

The energy storage circuit consists of a diode bridge Z1, a voltage dependent resistor Rw, a diode D1, a resistor R1, a high impedance resistor R0, a high voltage capacitor Cg, a current limiting fuse FB and pin line interfaces Ea and Eb; the withstand voltage of the high-voltage capacitor Cg is more than 150V, and the capacitance is more than 100 mu F; the resistance value of the high-impedance resistor R0 is greater than 2M omega, and the high-impedance resistor R0 is connected with the high-voltage capacitor Cg in parallel, so that the residual electric quantity stored by the high-voltage capacitor Cg is discharged in the resistor R0, and the electric quantity stored by the high-voltage capacitor Cg when the high-voltage capacitor Cg does not work in daily life is zero; the pin line interfaces Ea and Eb are interfaces connected with a digital detonator through a network, the digital detonator provides a direct current working voltage smaller than 20V for the digital control circuit, the digital detonator modulates the direct current voltage of 20V to communicate with the digital control circuit, and the digital control circuit communicates with the digital detonator through current modulation; the digital detonator also provides a direct current working voltage which is more than 60V to the pin line interfaces Ea and Eb through the network so as to charge a high-voltage capacitor Cg in the energy storage circuit. The digital detonator is a master control digital detonator in the network blasting system, and the master control digital detonator can be connected with a plurality of high-energy capacitor energy storage plasma igniter digital electronic detonators through network lines.

As shown in fig. 7, the control circuit of embodiment 2 is different from the control circuit of embodiment 1 in that a micro-processing circuit is removed; the plasma igniter circuit and the tank circuit in the embodiment 2 are the same as those in the embodiment 1; the control circuit and the plasma igniter circuit are the same as those in the embodiment 1, and are both arranged in the end socket of the detonator, and the energy storage circuit is plastically packaged in the capacitor energy storage circuit body; the digital delay of the high-energy capacitor energy storage plasma igniter is realized by controlling the high-energy capacitor energy storage plasma igniter to detonate through the delay of the network digital igniter.

The control circuit consists of resistors R21 and R22, a capacitor C21 and an MOSFET switching tube NM; the D pole and the G pole of the MOSFET switch tube NM are connected with the output ends of the V +, SIN and GND of the energy storage circuit through a high-strength coated insulated multi-core lead by a resistor R21 and a ground wire GND; the input ends V +, SIN and V-of the energy storage circuit are connected with the digital detonator through a three-core network cable; the digital detonator provides direct current of more than 60V and is connected with the input end V + and the V-end of the energy storage circuit through a network; the digital detonator provides a trigger signal SIN larger than 40V and is connected to the input end SIN end of the energy storage circuit through a network; when the digital detonator provides direct current of more than 60V and is connected with the input end V + and V-end of the energy storage circuit through a network, the V + and V-power supply charges the high-voltage capacitor Cg through the diode bridge Z1, the diode D21 and the resistor R21, when the high-voltage capacitor Cg is fully charged, the digital detonator provides a trigger signal SIN of more than 40V, the SIN trigger signal triggers the G pole of the MOSFET switching tube NM through the three-core network, the high-strength coated insulated multi-core lead, the resistor R21 and the anti-electromagnetic interference capacitor C21, and at the moment, the D pole and the S pole of the MOSFET switching tube NM are conducted to discharge the high-voltage capacitor Cg in the plasma igniter circuit to detonate the detonator.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; the capacitor energy storage device and the detonator body in the high-energy capacitor energy storage plasma igniter digital electronic detonator of the utility model are arranged in a split way, and the capacitor energy storage device can be designed in the detonator body to form an integrated high-energy capacitor energy storage plasma igniter digital electronic detonator; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention.

Claims (8)

1. The utility model provides a digital electric initiating device of high energy electric capacity energy storage plasma igniter, includes plastic housing (10), its characterized in that: an explosive sealing cover (20) is arranged at one end of the plastic shell (10), an initiator sealing head (30) is arranged at the other end of the plastic shell (10), the initiator sealing head (30) is of a hollow screw structure, an insulated conducting wire (40) is led out from one end of the initiator sealing head (30), the other end of the initiator sealing head (30) is inserted into the plastic shell (10) to be arranged, the initiator sealing head (30) is fixedly connected with the plastic shell (10) through threads, and a main explosive (50) is filled in the shell of the plastic shell (10);

the detonator seal head (30) is connected with a signal output end of the capacitive energy storage device (60) through an insulated wire (40), and a signal input end of the capacitive energy storage device (60) is connected with the network digital detonator through a network pin wire (70).

2. The digital electric detonator of the high-energy capacitor energy-storage plasma igniter according to claim 1, wherein: one end of the detonator sealing head (30) is provided with a control tube (301), the control tube (301) is connected with a steel sleeve (303) in a pressing mode into a whole through a packaging clamping waist (302), a control circuit board (304) is packaged in the control tube (301), the control circuit board (304) is connected with a plasma ignition tool (306) through an ignition lead (305), the plasma ignition tool (306) is in contact with an initiating explosive (307), and the initiating explosive (307) is in contact with a initiating explosive (308).

3. The digital electric detonator of the high-energy capacitor energy-storage plasma igniter, according to claim 2, wherein: the plasma igniter (306) is manufactured by adopting a printed circuit board process, a pair of conductive copper foils is arranged on two sides of the printed circuit board in parallel, an anode bonding pad A1 is arranged on one conductive copper foil, a cathode bonding pad B1 is arranged on the other conductive copper foil, a copper foil bulge c and a copper foil bulge d are arranged between the two conductive copper foils, the distance between the copper foil bulge c and the copper foil bulge d is less than 0.2 mm, a copper foil bridge line E is also arranged between the copper foil bulge c and the copper foil bulge d, the line width of the copper foil bridge line E is less than 75 microns, and the resistance value of the copper foil bridge line E approaches zero.

4. The digital electric detonator of the high-energy capacitor energy-storage plasma igniter, according to claim 2, wherein: the plasma igniter (306) is manufactured by adopting a printed circuit board process, a pair of conductive copper foils is arranged on two sides of the printed circuit board in parallel, an anode pad A1 is arranged on one conductive copper foil, a cathode pad B1 is arranged on the other conductive copper foil, a patch type plasma discharge thin-film device H1 is welded between the two conductive copper foils, the inside of the discharge thin-film device H1 is composed of a conductive metal layer c and a conductive metal layer d, the distance between the conductive metal layer c and the conductive metal layer d is smaller than 0.2 mm, a metal line bridge foil E is further arranged between the conductive metal layer c and the conductive metal layer d, the line width of the metal line bridge foil E is smaller than 75 microns, and the resistance value of the metal line bridge foil E approaches zero.

5. The digital electric detonator of the high-energy capacitor energy-storage plasma igniter as claimed in any one of claims 3 or 4, wherein: the capacitor energy storage device (60) comprises a diode bridge Z1, a voltage dependent resistor Rw, a diode D1, a resistor R1, a high impedance resistor R0, a high voltage capacitor Cg and a current limiting fuse FB, and the circuit structure of the capacitor energy storage device (60) is as follows:

the input end of the diode bridge Z1 is connected with the network digital initiator through a network pin wire (70), and the energy storage loop formed by the piezoresistor Rw, the diode D1, the resistor R1, the high-impedance resistor R0 and the high-voltage capacitor Cg is connected in parallel with the two ends of the output end of the diode bridge Z1.

6. The digital electric detonator of claim 5, wherein: the control circuit board (304) is provided with a microprocessor IC1, a current amplifier IC2, a triode T1-T7, a diode D2-D3, a voltage stabilizing diode W1, a MOSFET switch tube NM, a resistor R2-R15 and an active capacitor C1, and the peripheral circuit structure of the microprocessor IC1 is as follows:

a pin 1 of the microprocessor IC1 is connected with one end of a resistor R8 in parallel and then is connected with a collector of a triode T5;

the pin 4 of the microprocessor IC1 is connected with one end of a resistor R11, the other end of a resistor R8, an emitter of a triode T4, an emitter of a triode T3 and the anode of an electrode capacitor C1, and the emitter of a triode T2 is connected with the 3.3V power input end;

the base of the triode T5 is connected with one end of a resistor R9 in parallel and then connected with the collector of a triode T4, the base of the triode T4 is connected with the anode of a diode D2, the cathode of the diode D2 is connected with one end of a resistor R7 in parallel and then connected with one end of a resistor R6, the collector of the triode T2 is connected with one end of a resistor R4, and the base of the triode T2 is connected with one end of a resistor R5 in parallel and then connected with the cathode of a zener diode W1;

the other end of the resistor R4 is connected with the other end of the resistor R5 in parallel, the other end of the resistor R6 and the emitter of the triode T1 are connected with the pin 1 of the current amplifier IC 2;

the pin 3 of the current amplifier IC2 is connected with the collector of a triode T3;

the collector of the triode T1 is connected with one end of a resistor R2 in parallel and then connected with the positive electrode output end of a capacitive energy storage device (60), and the base of the triode T1 is connected with the other end of a resistor R2 in parallel and then connected with one end of a resistor R3;

a pin 5 of the microprocessor IC1 is connected with the other end of the resistor R11 in parallel and then connected with one end of a resistor R12, the other end of the resistor R12 is connected with one end of a resistor R13 in parallel and then connected with the base of a triode T6, the collector of the triode T6 is connected with the base of a triode T7, the emitter of the triode T7 is connected with one end of a resistor R15, the collector of the triode T7 is connected with one end of a resistor R14 in parallel and then connected with the gate of a switch tube NM, the source of the switch tube NM is connected with the negative electrode of a diode D3 in parallel and then connected with the positive input end of the plasma ignition tool (306), and the drain of the switch tube NM is connected with the other end of a resistor R15 in parallel and then connected with the positive output;

the pin 7 of the microprocessor IC1 is connected with the anode of a diode D3;

the pin 8 of the microprocessor IC1 is connected with a resistor R10 in series and then is connected with the base electrode of a triode T3;

the negative electrode input end of the plasma igniter (306) is sequentially connected with the other end of the resistor R14, the emitting electrode of the triode T6, the other end of the resistor R13, the pin 2 of the microprocessor IC1, the emitting electrode of the triode T5, the other end of the resistor R9, the negative electrode of the polar capacitor C1, the positive electrode of the voltage stabilizing diode W1, the other end of the resistor R7, the pin 2 of the current amplifier IC2, and the other end of the resistor R3 is connected with the negative electrode output end of the capacitor energy storage device (60).

7. The digital electric detonator of claim 5, wherein: the control circuit board (304) is provided with a MOSFET switch tube NM1, a resistor R22, a resistor R23 and a capacitor C21, and the peripheral circuit structure of the MOSFET switch tube NM1 is as follows:

the source electrode of the MOSFET switching tube NM1 is connected with the positive electrode input end of the plasma igniter (306);

the drain electrode of the MOSFET switching tube NM1 is connected with the anode output end of the capacitive energy storage device (60);

the grid of the MOSFET switching tube NM1 is connected with one end of a resistor R23 in parallel, one end of a capacitor C21 is connected with one end of a resistor R22, and the other end of the resistor R22 is connected with an SIN port of a capacitor energy storage device (60);

the other end of the resistor R23 is connected in parallel with the negative input end of the plasma igniter (306), and the other end of the capacitor C21 is connected with the negative output end of the capacitor energy storage device (60).

8. The digital electric detonator of claim 6, wherein: the model of the microprocessor IC1 is ES7P001 FGSA;

the current amplifier IC2 is model RLR 763.

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