阅读说明：本技术 高能量电容储能等离子点火具数码电*** (High-energy capacitance energy-storage plasma igniter digital electric detonator ) 是由 任流润 郭建国 于 2019-11-27 设计创作，主要内容包括：本发明高能量电容储能等离子点火具数码电雷管,属于无起爆药高能量电容储能等离子点火具数码电雷管技术领域；所要解决的技术问题为：提供一种高能量电容储能等离子点火具数码电雷管结构的改进；解决该技术问题采用的技术方案为：包括装药管和控制管组成的雷管,装药管的一端封闭,装药管的另一端通过卡腰a与控制管的一端连接为一体,控制管的另一端设置有卡腰b；装药管由封口端向外依次设置有主猛炸药、副猛炸药、激发猛炸药,激发猛炸药设置在加强套内,加强套的外侧设置有等离子点火具,等离子点火具的正负电极焊盘上焊接引出电极线,卡腰a的内侧填充有第一密封塞,电极线穿过第一密封塞接入控制管内侧设置的控制电路板中；本发明应用于电雷管。(The invention relates to a high-energy capacitor energy-storage plasma igniter digital electric detonator, belonging to the technical field of high-energy capacitor energy-storage plasma igniter digital electric detonators without initiating explosive; the technical problem to be solved is as follows: the improvement of the structure of the digital electric detonator of the high-energy capacitance energy-storage plasma igniter is provided; the technical scheme for solving the technical problem is as follows: the detonator comprises a detonator consisting of a charge tube and a control tube, wherein one end of the charge tube is closed, the other end of the charge tube is connected with one end of the control tube into a whole through a clamping waist a, and the other end of the control tube is provided with a clamping waist b; the charging tube is provided with a main high explosive, an auxiliary high explosive and an excitation high explosive from a sealing end to the outside in sequence, the excitation high explosive is arranged in a reinforcing sleeve, a plasma igniter is arranged on the outer side of the reinforcing sleeve, an electrode wire is welded on a positive electrode pad and a negative electrode pad of the plasma igniter, the inner side of a clamping waist a is filled with a first sealing plug, and the electrode wire passes through the first sealing plug and is connected into a control circuit board arranged on the inner side of the control tube; the invention is applied to the electric detonator.)

1. High energy electric capacity energy storage plasma igniter digital electric detonator, its characterized in that: the detonator comprises a detonator consisting of a charging tube (10) and a control tube (20), wherein one end of the charging tube (10) is closed, the other end of the charging tube (10) is connected with one end of the control tube (20) into a whole through a clamping waist a, and the other end of the control tube (20) is provided with a clamping waist b;

the charging tube (10) is provided with a main high explosive (10-1), an auxiliary high explosive (10-2) and an excitation high explosive (10-3) from a sealing end to the outside in sequence, the excitation high explosive (10-3) is arranged in a reinforcing sleeve (10-5), a plasma igniter (10-4) is arranged on the outer side of the reinforcing sleeve (10-5), an extraction electrode wire (10-7) is welded on a positive electrode pad and a negative electrode pad of the plasma igniter (10-4), the inner side of a clamping waist a is filled with a first sealing plug (10-6), and the electrode wire (10-7) penetrates through the first sealing plug (10-6) and is connected into a control circuit board (20-1) arranged on the inner side of the control tube (20);

a second sealing plug (20-2) is filled on the inner side of the clamping waist b, a detonator leg wire (30) penetrates through the second sealing plug (20-2), and the wire inlet end of the detonator leg wire (30) is connected to the other end of the control tube (20);

the detonator leg wire (30) is connected with the control circuit board (20-1) after being connected with the control tube (20);

and the control chip integrated on the control circuit board (20-1) is also connected with an energy storage capacitor module.

2. The high-energy capacitor energy-storage plasma igniter digital electric detonator according to claim 1, wherein: the control tube (20) and a control circuit board (20-1) arranged in the control tube (20) are designed integrally, a control circuit and an energy storage capacitor module are integrated on the control circuit board (20-1), and the control circuit and the energy storage capacitor module are packaged in the control tube (20).

3. The high-energy capacitor energy-storage plasma igniter digital electric detonator according to claim 1, wherein: the control tube (20) and a control circuit board (20-1) arranged inside the control tube (20) are designed in a split mode, a control circuit is integrated on the control circuit board (20-1), the control circuit is packaged in the control tube (20), an energy storage capacitor module is packaged on the inner side of an energy storage circuit plastic package body (40), the control tube (20) is connected with one end of the energy storage circuit plastic package body (40) through a waterproof flexible connecting wire (50), and the other end of the energy storage circuit plastic package body (40) is connected with a wire inlet end of a detonator foot wire (30).

4. The high-energy capacitor energy-storage plasma igniter digital electric detonator according to claim 2, wherein: the pipe diameter size and the inner wall thickness of the medicine loading pipe (10) and the control pipe (20) are the same.

5. The high-energy capacitor energy-storage plasma igniter digital electric detonator according to claim 3, wherein: the inner diameters of the medicine loading pipe (10) and the control pipe (20) are the same, and the outer diameter of the pipe is different from the thickness of the inner wall of the pipe.

6. The high-energy capacitor energy-storage plasma igniter digital electric detonator according to claim 1, wherein: the plasma igniter (10-4) is manufactured by adopting a printed circuit board process, a pair of conductive copper foils are arranged on the upper side and the lower side of the plasma igniter (10-4) in parallel, an anode pad A1 is arranged on the conductive copper foil on the upper side, a cathode pad B1 is arranged on the conductive copper foil on the lower side, a pair of bulges are oppositely arranged in the middle of the conductive copper foils on the upper side and the lower side, a copper foil bridge line E with a micron-sized line width is also arranged between the bulges, and the resistance value of the copper foil bridge line E approaches to zero.

7. The high-energy capacitor energy-storage plasma igniter digital electric detonator according to claim 1, wherein: the plasma igniter (10-4) is manufactured by adopting a printed circuit board process, a pair of conductive copper foils are arranged on the upper side and the lower side of the plasma igniter (10-4) in parallel, an anode pad A1 is arranged on the conductive copper foil on the upper side, a cathode pad B1 is arranged on the conductive copper foil on the lower side, a patch type ignition bridge membrane device H1 is welded in the middle of the conductive copper foil on the upper side and the lower side, the patch type ignition bridge membrane device H1 is composed of an upper conductive metal layer c and a lower conductive metal layer d, a metal bridge wire with micron-sized line width is arranged between the conductive metal layer c and the conductive metal layer d, and the resistance value of the metal bridge wire approaches zero.

8. The high-energy capacitor energy-storage plasma igniter digital electric detonator according to claim 1, wherein: the energy storage capacitor module internally comprises a bridge D1, a diode D2, a resistor R1 and an energy storage capacitor Cg, and the circuit structure of the energy storage capacitor module is as follows:

the input end of the electric bridge D1 is connected with the main machine of the detonator through a detonator leg wire (30), and the energy storage loop formed by the diode D2, the resistor R1 and the energy storage capacitor Cg is connected in parallel with the two ends of the output end of the electric bridge D2.

9. The high-energy capacitor energy storage plasma igniter digital electric detonator according to any one of claims 4 or 5, wherein:

the control circuit board (20-1) is internally provided with a microprocessor IC1, a current amplifier IC2, a triode T1-T7, a diode D3-D4, a voltage stabilizing diode W1, a MOSFET switching tube NM, a resistor R2-R14 and a polar 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 the other end of the resistor R8, the emitter of the triode T4, the emitter of the triode T3, the anode of the polar capacitor C1, and the emitter of the 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 D3, the cathode of the diode D3 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 anode output end of the energy storage capacitor module, 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 one end of a resistor R11, the other end of the resistor R11 is connected with one end of the resistor R12 in parallel and then connected with a base of a triode T6, a collector of the triode T6 is connected with a base of a triode T7, an emitter of the triode T7 is connected with one end of the resistor R13, a collector of the triode T7 is connected with one end of the resistor R14 in parallel and then connected with a gate of a switching tube NM, a source of the switching tube NM is connected with a negative electrode of a diode D4 in parallel and then connected with an anode input end of a plasma igniter (10-4), and a drain of the switching tube NM is connected with the other end of the resistor R13 in parallel and then connected with an anode output end of an energy storage;

the pin 7 of the microprocessor IC1 is connected with the anode of a diode D4;

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 (10-4) is sequentially connected with the other end of the resistor R14, the emitting electrode of the triode T6, the other end of the resistor R12, 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 energy storage capacitor module.

10. The high-energy capacitor energy-storage plasma igniter digital electric detonator according to claim 9, wherein: one end of the detonator leg wire (30) is connected with the energy storage capacitor module, the other end of the detonator leg wire (30) is connected with the main detonator machine, and the main detonator machine outputs two power supply voltage specifications of low voltage less than or equal to 20VDC and high voltage more than or equal to 50 VDC;

when the detonator leg wire (30) provides a power supply with low voltage less than or equal to 20VDC for the electric detonator, a work debugging instruction is sent to a control circuit integrated on the control circuit board (20-1) for data exchange;

and when the detonator leg wire (30) provides a high-voltage power supply which is more than or equal to 50VDC for the electric detonator, the energy storage capacitor Cg in the energy storage capacitor module is charged.

Technical Field

The invention relates to a high-energy capacitor energy storage plasma igniter digital electric detonator, belonging to the technical field of high-energy capacitor energy storage plasma igniter digital electric detonators without initiating explosive.

Background

The basic charge structure of the existing industrial digital electronic detonator is shown in figure 1, and is characterized by mainly comprising a leg wire (2-1), a micro-processing circuit board (2-2), an electric ignition head (2-3), a reinforcing cap (2-4), an initiating explosive (2-5), a reinforcing cap (2-6), a booster explosive (2-7), a main charge (2-8), a main charge 1 (2-9) and a thickened metal shell (2-10); the initiating explosive (2-5) is the core explosive in the existing digital store detonator, generally adopts the initiating explosive which has higher collision friction sensitivity and can explode when meeting fire, and particularly adopts DDNP dinitrodiazophenol initiating explosive, so that the existing industrial electric detonator and digital electronic detonator are very easy to explode safety accidents in the daily production, transportation, storage and use processes, and the DDNP dinitrodiazophenol is used as the initiating explosive, which can generate a large amount of sewage in the explosive making process, and the discharged sewage contains highly toxic pollutants and is difficult to remove.

On the other hand, an electric ignition head is arranged in the existing industrial electric detonator and digital electronic detonator, the electric ignition head is formed by welding a thin resistance wire between a positive electrode and a negative electrode and then coating an ignition powder, the thin resistance wire of the electric ignition head is made of constantan or nickel-chromium material, the diameter of the thin wire is less than or equal to 0.04mm, the resistance value of the constantan wire is 0.7-1.0 omega, and the resistance value of the nickel-chromium wire is 2.5-3.0 omega; when the current connected to the two electrodes of the electric ignition head is larger than 0.18A, the resistance voltage drop is larger than 1V, and the electric ignition head can be ignited and ignited, so that the energy storage capacitor in the circuit of the existing digital electric detonator supplies the electric ignition head to discharge and ignite, the electric ignition head is a miniaturized patch capacitor which can be arranged in a detonator shell (the inner diameter is 6 mm), the capacitance capacity is smaller than or equal to 10 muf, the withstand voltage is smaller than or equal to 20V, and the energy storage is smaller than 20 mJ. And the igniter used in the existing digital electronic detonator charging structure is an electric ignition head, so that initiating explosive with very high sensitivity must be used in the digital electronic detonator charging structure, and the existing digital electronic detonator is very easy to explode and has safety accidents in the daily production, transportation, storage and use processes.

Disclosure of Invention

In order to overcome the defects in the prior art, the invention aims to solve the technical problems that: provides an improvement of a digital electric detonator structure of a high-energy capacitance energy-storage plasma igniter.

In order to solve the technical problems, the invention adopts the technical scheme that: the high-energy capacitance energy-storage plasma igniter digital electric detonator comprises a detonator consisting of a charge tube and a control tube, wherein one end of the charge tube is closed, the other end of the charge tube is connected with one end of the control tube into a whole through a clamping waist a, and the other end of the control tube is provided with a clamping waist b;

the charging tube is sequentially provided with a main high explosive, an auxiliary high explosive and an excitation high explosive from a sealing end to the outside, the excitation high explosive is arranged in a reinforcing sleeve, a plasma igniter is arranged on the outer side of the reinforcing sleeve, lead-out electrode wires are welded on positive and negative electrode pads of the plasma igniter, a first sealing plug is filled on the inner side of a clamping waist a, and the electrode wires penetrate through the first sealing plug and are connected into a control circuit board arranged on the inner side of the control tube;

a second sealing plug is filled on the inner side of the clamping waist b, a detonator leg wire penetrates through the second sealing plug, and the wire inlet end of the detonator leg wire is connected to the other end of the control tube;

the detonator leg wire is connected with the control circuit board after being connected with the control tube;

and the control chip integrated on the control circuit board is also connected with an energy storage capacitor module.

The control tube and the control circuit board arranged in the control tube are designed integrally, the control circuit board is integrated with a control circuit and an energy storage capacitor module, and the control circuit and the energy storage capacitor module are packaged in the control tube.

The control tube and the control circuit board arranged in the control tube are designed in a split mode, the control circuit board is integrated with a control circuit, the control circuit is packaged in the control tube, the energy storage capacitor module is packaged on the inner side of the energy storage circuit plastic package body, the control tube is connected with one end of the energy storage circuit plastic package body through a waterproof flexible connecting wire, and the other end of the energy storage circuit plastic package body is connected with a wire inlet end of a detonator leg wire.

The pipe diameter size and the inner wall thickness of the medicine loading pipe and the control pipe are the same.

The inner diameters of the medicine loading pipe and the control pipe are the same, and the outer diameter of the medicine loading pipe and the thickness of the inner wall of the medicine loading pipe are different from each other.

The plasma igniter is manufactured by adopting a printed circuit board process, a pair of conductive copper foils is arranged on the upper side and the lower side of the plasma igniter in parallel, an anode bonding pad A1 is arranged on the conductive copper foil on the upper side, a cathode bonding pad B1 is arranged on the conductive copper foil on the lower side, a pair of protrusions are oppositely arranged in the middle of the conductive copper foils on the upper side and the lower side, a copper foil bridge line E with a micron-sized line width is further arranged between the protrusions, and the resistance value of the copper foil bridge line E is close to zero.

The plasma igniter is manufactured by adopting a printed circuit board process, a pair of conductive copper foils is arranged on the upper side and the lower side of the plasma igniter in parallel, an anode pad A1 is arranged on the conductive copper foil on the upper side, a cathode pad B1 is arranged on the conductive copper foil on the lower side, a patch type ignition bridge membrane device H1 is welded in the middle of the conductive copper foil on the upper side and the lower side, the patch type ignition bridge membrane device H1 is composed of an upper conductive metal layer c and a lower conductive metal layer d, a metal bridge wire with micron-sized line width is arranged between the conductive metal layer c and the conductive metal layer d, and the resistance value of the metal bridge wire approaches to zero.

The energy storage capacitor module internally comprises a bridge D1, a diode D2, a resistor R1 and an energy storage capacitor Cg, and the circuit structure of the energy storage capacitor module is as follows:

the input end of the electric bridge D1 is connected with the main machine of the detonator through a detonator leg wire, and the energy storage loop formed by the diode D2, the resistor R1 and the energy storage capacitor Cg is connected in parallel with two ends of the output end of the electric bridge D2.

The control circuit board is provided with a microprocessor IC1, a current amplifier IC2, a triode T1-T7, a diode D3-D4, a voltage stabilizing diode W1, a MOSFET switch tube NM, a resistor R2-R14 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 the other end of the resistor R8, the emitter of the triode T4, the emitter of the triode T3, the anode of the polar capacitor C1, and the emitter of the 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 D3, the cathode of the diode D3 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 anode output end of the energy storage capacitor module, 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 to one end of a resistor R11, the other end of the resistor R11 is connected in parallel to one end of the resistor R12 and then connected to a base of a transistor T6, a collector of the transistor T6 is connected to a base of a transistor T7, an emitter of the transistor T7 is connected to one end of the resistor R13, a collector of the transistor T7 is connected in parallel to one end of the resistor R14 and then connected to a gate of a switching tube NM, a source of the switching tube NM is connected in parallel to a negative electrode of a diode D4 and then connected to an anode input end of a plasma igniter, and a drain of the switching tube NM is connected in parallel to the other end of the resistor R13 and then connected to an anode output end of the energy;

the pin 7 of the microprocessor IC1 is connected with the anode of a diode D4;

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 R12, 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 energy storage capacitor module.

One end of the detonator leg wire is connected with the energy storage capacitor module, the other end of the detonator leg wire is connected with the main detonator machine, and the main detonator machine outputs two power supply voltage specifications of which the low voltage is less than or equal to 20VDC and the high voltage is more than or equal to 50 VDC;

when the detonator pin wire provides a power supply with low voltage less than or equal to 20VDC to the electric detonator, a work debugging command is sent to a control circuit integrated on a control circuit board for data exchange;

and when the detonator lead supplies a power supply with high voltage more than or equal to 50VDC to the electric detonator, the energy storage capacitor Cg in the energy storage capacitor module is charged.

Compared with the prior art, the invention has the beneficial effects that: the invention mainly aims at that a high-energy capacitor without initiating explosive instantaneously carries out high-voltage and high-current discharge between the electrodes of the plasma igniter, so that a central bridge foil of the plasma igniter forms a punctiform high-voltage and high-temperature deflagration plasma gaseous shock wave, a required energy storage capacitor with the electric energy more than or equal to 0.1J, and a specially designed control discharge circuit and an electric detonator charging structure thereof; the invention is different from the energy storage capacitor of the electric detonator with the initiating explosive charging structure, and adopts a capacitor with low voltage, low capacity and small volume, the electric energy stored by the capacitor is less than 25mJ millicoke, and the capacitor can only discharge and heat on a fine resistance wire of an electric ignition head, and ignite the initiating explosive through the igniting explosive to form gas flame to ignite the initiating explosive, and the finally ignited initiating explosive is converted into detonation to excite the high explosive to carry out detonation wave output;

the invention improves the existing digital electric detonator control circuit and bus, adopts a digital electric detonator which can meet the requirements of triggering and controlling the electric energy of a high-voltage energy storage capacitor to discharge in a plasma igniter, instantaneously forms high-voltage and high-temperature plasma gaseous shock waves to excite a high explosive, and forms detonation wave output without initiating explosive; the invention adopts a power supply and communication shared bus, and adopts a hopping power supply mode with low voltage less than or equal to 20VDC and high voltage more than or equal to 50VDC and a two-wire bus shared by communication, so that the control circuit has high voltage resistance, high capacitance energy storage and strong anti-electromagnetic interference, and the electric detonator provided by the invention has high reliability, and is safer and more stable when in use.

Drawings

The invention is further described below with reference to the accompanying drawings:

FIG. 1 is a schematic diagram of a conventional digital electric detonator;

FIG. 2 is an enlarged view of a circuit structure of a plasma igniter according to a first embodiment of the invention;

FIG. 3 is an enlarged view of the circuit structure of a second embodiment of the plasma igniter of the invention;

fig. 4 is a structural diagram of a digital electric detonator according to a first embodiment of the invention;

fig. 5 is a circuit diagram of an internal control circuit board of the digital electric detonator according to the first embodiment of the present invention;

fig. 6 is a structural diagram of a digital electric detonator according to a second embodiment of the present invention;

fig. 7 is a circuit diagram of an internal control circuit board of the digital electric detonator according to the second embodiment of the present invention;

in the figure: the explosive-charging device comprises a charging tube 10, a control tube 20, a detonator leg wire 30, an energy storage circuit plastic package body 40, a waterproof flexible connecting wire 50, a main high explosive 10-1, an auxiliary high explosive 10-2, an exciting high explosive 10-3, a plasma igniter 10-4, a reinforcing sleeve 10-5, a first sealing plug 10-6, an electrode wire 10-7, a control circuit board 20-1 and a second sealing plug 20-2.

Detailed Description

As shown in fig. 1 to 7, the digital electric detonator for the high-energy capacitive energy-storage plasma igniter comprises a detonator composed of a charge tube (10) and a control tube (20), wherein one end of the charge tube (10) is closed, the other end of the charge tube (10) is connected with one end of the control tube (20) into a whole through a clamping waist a, and the other end of the control tube (20) is provided with a clamping waist b;

the charging tube (10) is provided with a main high explosive (10-1), an auxiliary high explosive (10-2) and an excitation high explosive (10-3) from a sealing end to the outside in sequence, the excitation high explosive (10-3) is arranged in a reinforcing sleeve (10-5), a plasma igniter (10-4) is arranged on the outer side of the reinforcing sleeve (10-5), an extraction electrode wire (10-7) is welded on a positive electrode pad and a negative electrode pad of the plasma igniter (10-4), the inner side of a clamping waist a is filled with a first sealing plug (10-6), and the electrode wire (10-7) penetrates through the first sealing plug (10-6) and is connected into a control circuit board (20-1) arranged on the inner side of the control tube (20);

a second sealing plug (20-2) is filled on the inner side of the clamping waist b, a detonator leg wire (30) penetrates through the second sealing plug (20-2), and the wire inlet end of the detonator leg wire (30) is connected to the other end of the control tube (20);

the detonator leg wire (30) is connected with the control circuit board (20-1) after being connected with the control tube (20);

and the control chip integrated on the control circuit board (20-1) is also connected with an energy storage capacitor module.

The control tube (20) and a control circuit board (20-1) arranged in the control tube (20) are designed integrally, a control circuit and an energy storage capacitor module are integrated on the control circuit board (20-1), and the control circuit and the energy storage capacitor module are packaged in the control tube (20).

The control tube (20) and a control circuit board (20-1) arranged inside the control tube (20) are designed in a split mode, a control circuit is integrated on the control circuit board (20-1), the control circuit is packaged in the control tube (20), an energy storage capacitor module is packaged on the inner side of an energy storage circuit plastic package body (40), the control tube (20) is connected with one end of the energy storage circuit plastic package body (40) through a waterproof flexible connecting wire (50), and the other end of the energy storage circuit plastic package body (40) is connected with a wire inlet end of a detonator foot wire (30).

The pipe diameter size and the inner wall thickness of the medicine loading pipe (10) and the control pipe (20) are the same.

The inner diameters of the medicine loading pipe (10) and the control pipe (20) are the same, and the outer diameter of the pipe is different from the thickness of the inner wall of the pipe.

The plasma igniter (10-4) is manufactured by adopting a printed circuit board process, a pair of conductive copper foils are arranged on the upper side and the lower side of the plasma igniter (10-4) in parallel, an anode pad A1 is arranged on the conductive copper foil on the upper side, a cathode pad B1 is arranged on the conductive copper foil on the lower side, a pair of bulges are oppositely arranged in the middle of the conductive copper foils on the upper side and the lower side, a copper foil bridge line E with a micron-sized line width is also arranged between the bulges, and the resistance value of the copper foil bridge line E approaches to zero.

The plasma igniter (10-4) is manufactured by adopting a printed circuit board process, a pair of conductive copper foils are arranged on the upper side and the lower side of the plasma igniter (10-4) in parallel, an anode pad A1 is arranged on the conductive copper foil on the upper side, a cathode pad B1 is arranged on the conductive copper foil on the lower side, a patch type ignition bridge membrane device H1 is welded in the middle of the conductive copper foil on the upper side and the lower side, the patch type ignition bridge membrane device H1 is composed of an upper conductive metal layer c and a lower conductive metal layer d, a metal bridge wire with micron-sized line width is arranged between the conductive metal layer c and the conductive metal layer d, and the resistance value of the metal bridge wire approaches zero.

The energy storage capacitor module internally comprises a bridge D1, a diode D2, a resistor R1 and an energy storage capacitor Cg, and the circuit structure of the energy storage capacitor module is as follows:

the input end of the electric bridge D1 is connected with the main machine of the detonator through a detonator leg wire (30), and the energy storage loop formed by the diode D2, the resistor R1 and the energy storage capacitor Cg is connected in parallel with the two ends of the output end of the electric bridge D2.

The control circuit board (20-1) is internally provided with a microprocessor IC1, a current amplifier IC2, a triode T1-T7, a diode D3-D4, a voltage stabilizing diode W1, a MOSFET switching tube NM, a resistor R2-R14 and a polar 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 the other end of the resistor R8, the emitter of the triode T4, the emitter of the triode T3, the anode of the polar capacitor C1, and the emitter of the 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 D3, the cathode of the diode D3 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 anode output end of the energy storage capacitor module, 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 one end of a resistor R11, the other end of the resistor R11 is connected with one end of the resistor R12 in parallel and then connected with a base of a triode T6, a collector of the triode T6 is connected with a base of a triode T7, an emitter of the triode T7 is connected with one end of the resistor R13, a collector of the triode T7 is connected with one end of the resistor R14 in parallel and then connected with a gate of a switching tube NM, a source of the switching tube NM is connected with a negative electrode of a diode D4 in parallel and then connected with an anode input end of a plasma igniter (10-4), and a drain of the switching tube NM is connected with the other end of the resistor R13 in parallel and then connected with an anode output end of an energy storage;

the pin 7 of the microprocessor IC1 is connected with the anode of a diode D4;

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 (10-4) is sequentially connected with the other end of the resistor R14, the emitting electrode of the triode T6, the other end of the resistor R12, 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 energy storage capacitor module.

One end of the detonator leg wire (30) is connected with the energy storage capacitor module, the other end of the detonator leg wire (30) is connected with the main detonator machine, and the main detonator machine outputs two power supply voltage specifications of low voltage less than or equal to 20VDC and high voltage more than or equal to 50 VDC;

when the detonator leg wire (30) provides a power supply with low voltage less than or equal to 20VDC for the electric detonator, a work debugging instruction is sent to a control circuit integrated on the control circuit board (20-1) for data exchange;

and when the detonator leg wire (30) provides a high-voltage power supply which is more than or equal to 50VDC for the electric detonator, the energy storage capacitor Cg in the energy storage capacitor module is charged.

The high-energy capacitor energy storage plasma igniter digital electric detonator provided by the invention has the advantages that the energy storage of the capacitor is more than 0.1 joule, the plasma igniter is supported to discharge, and plasma shock waves are formed to excite high explosive to form detonation waves for output.

In practical use, the invention provides two implementation modes in total to realize the use effects of capacitive energy storage and discharge output:

wherein example 1 is: a high-capacity electrolytic capacitor with the length larger than the diameter (the length-diameter ratio is larger than 5) is adopted as an energy storage device to be arranged on a control circuit board 20-1 to form an integrated high-energy capacitor energy storage plasma igniter digital electric detonator;

wherein example 2 is: a high-capacity electrolytic capacitor with the length larger than the diameter (the length-diameter ratio is larger than 5) is used as an energy storage device and is arranged in the energy storage circuit plastic package body 40 to form the split high-energy capacitor energy storage plasma igniter digital electric detonator.

Because the high-voltage energy storage digital circuit triggers the high-voltage plasma igniter, high-voltage and high-current discharge is instantaneously generated between the electrodes of the high-voltage plasma igniter, and punctiform high-pressure, high-temperature and plasma gaseous shock waves are formed at the center of the plasma igniter, so that the conventional standard energy storage capacitor has a large volume and cannot be installed in a detonator shell, and the energy storage capacitor with the length-diameter ratio larger than 5 and a corresponding capacitive energy storage control circuit are designed;

because the conventional electric ignition head is adopted as an ignition tool in the existing digital electric detonator, a digital circuit in the detonator controls the low-voltage energy storage capacitor to discharge and release heat to the electric ignition head, the ignition powder forms gas flame to ignite the initiating explosive, and then the initiating explosive forms detonation initiation main charge; therefore, the explosive and the bus shared by the control, communication and power supply exist in the charging structure of the existing digital electric detonator, the charging structure is a low-voltage resistant circuit bus with the direct-current power supply voltage less than 20V, and the designed control circuit and the bus shared by the two-wire system communication and power supply have weak electromagnetic interference resistance and are easy to cause misoperation in the control process; the invention adopts a power supply and communication shared bus, and adopts a hopping power supply mode from low voltage (less than or equal to 20 VDC) to high voltage (more than or equal to 50 VDC) and a two-wire bus shared by communication, so that the control circuit has high voltage resistance, high capacitance energy storage and strong electromagnetic interference resistance, and the electric detonator provided by the invention has high reliability, and is safer and more stable when in use.

As shown in fig. 2 and 3, the plasma igniter used in the "integrated plasma igniter digital electric detonator" and the "split plasma igniter digital electric detonator" provided by the present invention is mainly characterized in that a printed circuit board or an insulating board is etched by adopting a vacuum sputtering metal film to form a bridge foil circuit electrode with a micron-sized resistance approaching zero;

FIG. 3 shows a plasma igniter, wherein black is a circuit copper clad surface, A1 and B1 are positive and negative electrode pads, c and d are conductive copper foil protrusions, and a bridge foil with micron-sized line width is arranged between the c and d conductive copper foil protrusions; in practical arrangement, the conductive metal layers c and d may be designed as an integral body with the conductive copper foil (as shown in fig. 2), or may be separately arranged as a discharge thin film device H1, where the discharge thin film device H1 is a plasma discharge device, and the device is a thin film circuit with micron-sized resistance approaching zero formed on an insulating plate (ceramic plate or other insulating material) by etching with a vacuum sputtering metal film, where the thickness of the insulating plate of the discharge thin film device H1 is less than 0.5mm, the width is less than 2.5mm, and the height is less than 3mm, a bridge foil with micron-sized line width is formed between the c and d conductive metal layers, and the plasma discharge device H1 is welded on the copper-clad surface of the black circuit of the printed circuit board, and the c and d conductive metal layers are electrically connected with the positive and negative electrode pads a1 and B1, respectively; the carrier for positive and negative electrode discharge of the plasma igniter is a bridge foil with micron-sized line width, and the resistance value of the bridge foil is close to zero.

As shown in fig. 4, which is a structural diagram of an electric detonator in example 1 of the present invention, a 10-1 main high explosive adopts hexogen RDX, a 10-2 secondary high explosive adopts hexogen RDX, a 10-3 secondary high explosive adopts taian PETN, a 10-5 reinforcing sleeve adopts metal steel, high strength aluminum or copper material, a 10-6 first sealing plug and a 20-2 second sealing plug adopt engineering plastics, and a Cg high energy storage capacitor adopts an electrolytic capacitor with a length-diameter ratio larger than 5; the diameter round surface of the 10-4 plasma igniter and the 10-3 high explosive excited by the plasma igniter are tightly assembled in a seamless manner.

As shown in fig. 5, the circuit diagram of the control board for controlling the circuit in the tube according to embodiment 1 of the present invention is mainly characterized by comprising an IC1 microprocessor, an IC2 current amplifier, a triode T1-T7, a bridge D1, diodes D2-D4, a zener diode W1, a MOSFET switch NM, resistors R1-R14, a capacitor C1, a high energy storage capacitor Cg, and a plasma igniter.

The energy storage capacitor module is a control circuit independent of the high-voltage plasma igniter circuit and mainly comprises a high-voltage energy storage capacitor Cg and a peripheral circuit; the input ends Ea and Eb of the electric bridge D1 are the access ends of the detonator leg wire of the connecting digital detonator power supply and communication sharing bus 30; the triode T1, the resistor R2, the resistor R3 and the current amplifier IC2 form a voltage division current amplifying circuit; the triode T2, the resistor R4, the resistor R5, the voltage regulator tube W1 and the capacitor C1 form a low-voltage stabilizing circuit; the triode T3-T5, the resistors R6-R10 and the diode D3 form a communication conversion circuit; the triode T6-T7, the MOSFET switch tube NM and the resistors R11-R14 form a driving switch circuit; the communication RX end of the microprocessor IC1 is connected with the collector of the T5, the communication TX end is connected with the base of the triode T3 through a resistor R10, the I/O end is connected with the base of the triode T6 through a resistor R11, wherein the microprocessor IC1 can select a 51-series 8-bit CPU special chip or adopt ES7P001FGSA, EFM8SB1, STM8L05xx, MAX-series micro-processing chips, and the IC2 current amplifier chip adopts RLR 763.

When in use, the detonator leg wire 30 is a two-wire bus connected between a digital detonator (short for a host) and the digital electric detonator (short for a slave) of the high-energy capacitance energy-storage plasma igniter of the invention, the host provides positive and negative power supplies for the slave, the host adopts a modulation voltage signal when in communication with the slave, and the modulation voltage signal received by the slave is divided by resistors R6 and R7 and is sent to a communication interface of a micro-processing chip IC1 to be received at an RX end through a diode D3, a triode T4, a resistor R9, a triode T5 and a resistor R8; the slave machine adopts a modulation current signal when communicating with the host machine, the host machine receives the modulation current signal of the slave machine and sends the modulation current signal to a TX end through a communication interface of a micro-processing chip IC1, and the current modulated by a current modulation circuit consisting of a resistor R10, a triode T3, a current amplifier IC2, a triode T1, a resistor R2 and a resistor R3 is received by the host machine through a bus 30; the I/O port of the microprocessing chip IC1 controls the cut-off and the conduction of the MOSFET switch tube NM, and controls the G pole of the MOSFET switch tube NM through a resistor R11, a triode T6, a triode T7, a resistor R13 and a resistor R14; when the I/O port of the microprocessing chip IC1 is at a high level, the G pole of the MOSFET switch tube NM is at a high level, and the D pole is conducted with the S pole; the electric energy stored in the high-voltage energy storage capacitor Cg is conducted to a plasma igniter through a D pole and an S pole of the MOSFET switch tube to discharge to generate plasma shock waves.

The voltage of a two-wire bus detonator pin wire 30 connected between the digital detonator (host) and the digital electric detonator (slave) of the high-energy capacitance energy-storage plasma igniter is a power supply and communication shared bus with two voltage systems of low voltage less than or equal to 20VDC and high voltage more than or equal to 50VDC provided by the host; when the voltage of a pin 30 of a two-wire bus detonator connected between the digital detonator (a host) and the digital electric detonator (a slave) of the high-energy capacitance energy-storage plasma igniter is less than or equal to 20VDC, the digital detonator is used for work debugging and communication between the host and the slave, and when the voltage is more than or equal to 50VDC, the digital detonator is used as the host to charge a high-voltage capacitor Cg in a slave control circuit.

As shown in fig. 6, the structure diagram of the split plasma igniter digital electric detonator of the invention is composed of a round diameter variable wall thickness basic detonator part 10, a digital detonator part 20, a waterproof flexible connecting wire 50, a high energy storage circuit plastic package body 40, a detonator leg wire 30, and clamping waist parts a and b; the basic structure of the embodiment 2 is different from that of the embodiment 1 in that firstly, the detonator shell adopts a round-diameter and variable-wall-thickness basic detonator shell, and secondly, the bridge D1, the diode D2, the resistor R1 and the high-voltage energy storage capacitor Cg in the control circuit of the embodiment 1 are independently arranged in the high-energy storage circuit plastic package body 40; the high-energy storage circuit plastic package body 40 is electrically connected with the digital detonator part 20 through a waterproof flexible connecting wire 50 to form a split high-energy capacitance energy storage plasma igniter digital electric detonator structure;

the high-energy storage circuit plastic package body 40 is internally provided with a circuit board which is related to an electric bridge D1, a diode D2, a resistor R1 and a high-voltage energy storage capacitor Cg; all digital circuit parts except a bridge D1, a diode D2, a resistor R1 and a high-voltage energy storage capacitor Cg are welded on the 20-1 digital drive circuit board.

As shown in fig. 7, a circuit diagram of a digital electric detonator control circuit of a split plasma igniter of the invention is shown, and the control circuit used in embodiment 2 of the invention is basically the same as that used in embodiment 1, but the difference is that an electric bridge D1, a diode D2, a resistor R1 and a high-voltage energy storage capacitor Cg are split and separately arranged in a high-energy storage circuit plastic package body 40, and are connected to a 20-1 digital drive circuit board inside a digital detonator part 20 through V +, HV + and GND terminals.

The detonator leg wire 30 is a two-wire bus connected between a digital detonator (host) and the high-energy capacitor energy storage plasma igniter digital electric detonator (slave), the host provides positive and negative power supplies for the slave, the host adopts a modulation voltage signal when communicating with the slave, and the slave receives the modulation voltage signal of the host and transmits the voltage division through resistors R6 and R7 to a microprocessor chip IC1 communication interface receiving RX end through a diode D3, a triode T4, a resistor R9, a triode T5 and a resistor R8; the slave machine adopts a modulation current signal when communicating with the host machine, the modulation current signal of the host machine receiving the slave machine is transmitted to a TX end through a communication interface of a micro-processing chip IC1, and the current modulated by a current modulation circuit consisting of a resistor R10, a triode T3, a triode T1, a resistor R2 and a resistor R3 is received by the host machine through a bus 30;

the I/O port (5 pins) of the microprocessor chip IC1 controls the cut-off and the conduction of the MOSFET switch tube NM, and controls the G pole of the MOSFET switch tube NM through a resistor R11, a triode T6, a triode T7, a resistor R13 and a resistor R14; when the I/O port (pin 5) of the microprocessor IC1 is at high level, the G pole of the MOSFET switch tube NM is at high level, and the D pole is conducted with the S pole; the electric energy stored in the high-voltage energy storage capacitor Cg is conducted to a plasma igniter through a D pole and an S pole of the MOSFET switch tube to discharge to generate plasma shock waves;

the I/O port (7 pins) of the microprocessor chip IC1 is connected with one end of a diode D4, the other end of the diode D4 is connected with the S pole of a MOSFET switch tube NM, and the microprocessor chip IC1 is used for checking whether the plasma igniter is damaged or not.

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; while the invention has been described in detail and with reference to the foregoing embodiments, it will 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; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.