CN110260737B - Explosion isolation pipe for sectionally and separately charging explosive in closed space and explosion isolation method - Google Patents

Abstract

The invention discloses a detonation isolation tube for sectionally and separately charging in a closed space and an explosion isolation method, wherein an explosion isolation device comprises an upper connecting terminal and a lower connecting terminal which are movably connected through threads; a first buffer cushion is arranged between the upper medicine tube and the flange structure, the first buffer cushion is of a hollow structure, and a second flexible detonating cord is arranged in a central through hole of the first buffer cushion; the outside of lower connecting terminal is provided with a plurality of annular metal expansion pipes of cascade connection, is provided with the second blotter between lower floor's grain and the flange. The detonation of the upper charge is converted into the detonation energy of the lower charge, and the lower cartridge is prevented from being impacted, damaged and symptomatic detonated after the explosive column of the upper charge is exploded through the comprehensive explosion-proof function.

Description

Explosion isolation pipe for sectionally and separately charging explosive in closed space and explosion isolation method

Technical Field

The invention belongs to the technical field of blasting, and relates to a detonation isolation tube for sectionally and separately charging in a closed space and an explosion isolation method.

Background

In the fields of mining, construction and military applications, a special pit body with a V-shaped cross section is usually required to be cut out on hard rock, as shown in fig. 1, the V-shaped pit body is a V-shaped pit with a wide upper part and a narrow lower part, the opening d of the pit body is smaller than the depth h and has a certain inclination angle requirement, so-called a variant funnel is commonly used for cutting. Fig. 2 shows a conventional layered blasting forming method of V-shaped pits, firstly, a plurality of cut holes are drilled on the upper layer of rock, wherein the cut holes comprise a center hole and an edge hole, and the positions of the cut holes are shown as a hole position schematic diagram below fig. 2. And installing small equivalent explosive in each hole, removing slag after the first layer of explosion, repeating the steps, performing blasting slag removal of the second layer, and finally forming the pit body through multiple blasting operations. The method has the problems of large drilling quantity, long operation time and high explosive consumption, and is difficult to meet the requirement of rapid forming in military application occasions.

Disclosure of Invention

The invention aims to provide a detonation isolation tube for sectionally and separately charging in a closed space and an explosion isolation method, which are used for effectively attenuating detonation waves of the first charging and avoiding the sympathetic explosion of the subsequent charging, so that a special V-shaped pit is excavated in hard rock at one time by adopting a small equivalent explosive through a secondary temporary blasting technology, and the rapid forming of the detonation pit is realized.

The specific technical scheme of the invention is as follows:

the utility model provides a sealed space segmentation separate charge detonation isolation tube which characterized in that: comprises an upper connecting terminal and a lower connecting terminal which are movably connected through threads;

the upper connecting terminal is of a flange structure, and an upper medicine tube of the upper medicine column unit is connected to the flange structure of the upper connecting terminal through threads; a first buffer cushion is arranged between the upper medicine tube and the flange structure; the first buffer cushion is of a hollow structure, and a second flexible detonating cord is arranged in the central through hole of the first buffer cushion; the outer side of the first buffer pad is provided with an annular groove and a straight groove which is communicated with the annular groove and the central through hole, and the annular groove and the straight groove are internally provided with a first flexible detonating cord; the first flexible detonating cord is contacted with the second flexible detonating cord;

the upper end of the lower connecting terminal is a sleeve, an inner sleeve and an outer sleeve are arranged outside the sleeve, a plurality of cascaded annular metal expansion pipes are arranged between the inner sleeve and the outer sleeve, the lower end of the lower connecting terminal is a flange, and the lower medicine pipes of the lower medicine column units are connected to the flange through threads; the lower medicine tube is internally provided with a lower medicine column, and a second buffer cushion is arranged between the lower medicine column and the flange in the lower medicine tube.

In the sealed space sectional spaced explosive-charging detonation-isolating pipe, a notch is formed in the inner ring of the annular metal expansion pipe, a straight groove is formed in the inner sleeve and the sleeve, corresponding to the notch, and a fourth flexible detonating cord is arranged in the annular metal expansion pipe, coiled in the pipe of the annular metal expansion pipe and the straight groove and is in contact with the second flexible detonating cord.

In the sealed space sectional and spaced explosive-charging detonation-isolating pipe, the pipe of the annular metal expansion pipe is filled with explosive.

In the sealed space sectional and spaced explosive-charging detonation-isolating pipe, the number of the annular metal expansion pipes is two.

In the sealed space sectional and spaced explosive-charging detonation-isolating pipe, a first metal expansion pipe is arranged in the tail end of the upper explosive pipe; the first metal expansion pipe is provided with internal threads and is connected with external threads on the flange structure of the upper connecting terminal.

In the sealed space sectional and spaced explosive-charging detonation-isolating pipe, the inner sleeve and the outer sleeve are both made of silicon rubber.

In the sealed space sectional and spaced explosive-charging detonation-isolating pipe, the upper explosive column and the lower explosive column are TNT explosives.

In the sealed space sectional spaced explosive-charging detonation-isolating pipe, the lower explosive-charging unit comprises a second explosive pipe and a bottom cover, and the lower explosive column is blocked inside the second explosive pipe by the bottom cover;

the sectional spaced charge and time-delay explosion propagation method for the closed space is characterized by comprising the following steps of:

【1】 Arranging a segmented spaced charge detonation isolation tube in the closed space;

【2】 The upper explosive column explodes to trigger the second flexible detonating cord to detonate;

【3】 After the second flexible detonating cord is detonated, the first flexible detonating cord is initiated, the first metal bulging tube is bulged, and the first buffer pad and the first metal bulging tube perform comprehensive action to buffer and separate the first explosion wave.

【4】 The second flexible detonating cord triggers the fourth flexible detonating cord and explosive filler in the cascaded annular metal expansion tube to explode, and the combined action of the inner sleeve, the outer sleeve, the upper connecting terminal, the lower connecting terminal, the second buffer pad and the annular metal expansion tube buffers and blocks the primary explosion wave again to prevent the lower explosive column from being detonated.

The beneficial technical effects of this project are as follows:

1. in the implementation of the invention, detonation of the upper charge is converted into detonation energy of the lower charge, and the lower charge is detonated, and energy control is one of the key problems of the project. The lower charge can be directly detonated due to the too small energy attenuation, and the lower charge cannot be detonated due to the too large energy attenuation, so that the explosion rejection is caused. The detonation isolation tube is designed, and the methods of hard isolation, soft clipping, gradual reduction of impact energy and the like are adopted, so that the explosion induction of the upper charge to the lower charge is blocked, and smooth propagation is realized. Firstly, adopting polymer material polyurethane with clipping at the front end and the rear end of a connecting terminal for reducing the intensity of detonation wave; secondly, an annular groove structure with a built-in flexible detonating cord is added into the buffer pad at the front end, so that detonation energy is prevented from spreading downwards; finally, two annular metal expansion pipes with explosive fillers are arranged in the middle of the explosion isolation pipe, expand under the action of detonation waves, further fill blast holes, block downward movement of detonation products, block propagation of the detonation waves, and prevent the lower cartridge from being impacted, destroyed and detonated after the explosive column on the upper part explodes through the comprehensive explosion isolation function.

2. The upper explosive column unit is detonated and then the lower explosive column unit is detonated after a period of time is delayed, so that secondary blasting of rock blasting is realized. When the upper explosive charge is exploded, the upper rock can be thrown off, a free surface is created for the lower explosive charge, and the blasting effect of the lower explosive charge is improved; simultaneously, the two-section type charging structure enables the upper charging to create a free surface for the lower charging, reduces the minimum resistance line of two charging blasting, and achieves one-time rapid forming of the V-shaped pit by using fewer charging.

Drawings

FIG. 1 is a schematic diagram of an ideal V-shaped dimple configuration;

FIG. 2 is a schematic diagram of a blasting forming step of a V-shaped pit in the prior art;

FIG. 3 is a schematic diagram of the rapid prototyping blasting apparatus layout of the present invention;

FIG. 4 is a schematic view of the composition of the blasting apparatus of the present invention;

FIG. 5 is a schematic diagram of the detonation unit of the blasting apparatus of the present invention;

FIG. 6 is a schematic view of the lower charge unit of the blasting apparatus of the present invention;

FIG. 7 is a schematic view of a detonation isolating tube of the blasting apparatus of the present invention;

FIG. 8 is a cross-sectional view of the structure of FIG. 7 A-A in accordance with the present invention;

FIG. 9 is a cross-sectional view of the structure of FIG. 7B-B in accordance with the present invention;

FIG. 10 is a schematic view of the structure of the bulkhead delay detonator of the present invention;

the reference numerals are: 1-a bottom cover; 6-lower layer of grains; 7-lower medicine tube; 8, a partition board delay detonator; 9-an annular metal expansion tube; 10-an outer sleeve; 11-upper connection terminals; 12-a first flexible detonating cord; 13-a first cushion pad; 14-a second flexible detonating cord; 15-upper layer grain; 16-upper cartridge; 17-detonating primer; 18-plugs; 19-detonator joint; 20-sealing cover; 21-an initiating component; 22-an upper cartridge unit; 23-explosion isolation pipe; 24-a lower cartridge unit; 31-a second cushion pad; 33-a flange; 34-a sleeve; 35-inner sleeve; 36-lower connection terminals; 41-a first metal expanded tube; 43-a third flexible detonating cord; 44-a fourth flexible detonating cord; 45-explosive filling; 51—a central through hole; 52-an annular groove; 53-straight grooves; 54-a drug core; 55-the crust; 61-notch; 81-delay detonator; 82-connecting a fire tube; 83-a baffle igniter; 91-detonator leads; 92-prefabricating holes; 93-blasting device; 94-upper explosion pit; 95-lower explosion pit; 96-rock.

Detailed Description

The invention aims to obtain V-shaped pits with special dimensions by one-time blasting forming on hard rock, improve pit forming efficiency, avoid operation dangers caused by secondary explosive filling blasting construction, adopt the scheme that a blasting device for two-section explosive is filled after drilling holes on the rock, and delay between an upper explosive and a lower explosive is controlled, so that the upper explosive is filled to create a free surface for the lower explosive, the minimum resistance line of two explosive blasting is reduced, and the one-time blasting rapid forming of the pit is realized by fewer explosive filling.

As shown in fig. 3, the main technical route of the present invention is as follows: firstly, a handheld drilling machine is used for drilling a blast hole 92 in the vertical direction in a rock 96, then a blasting device 93 integrated with an up-and-down charging and delay explosion transfer unit, namely a cylindrical explosion pit device, is placed into the blast hole 92 according to the set height for detonation, and is blasted for a long distance through a detonator lead 91, so that the first layer of charging close to the ground surface breaks the rock, throws slag, an inverted conical upper explosion pit 94 is formed on the ground surface, and a new free surface is created for the next layer of charging. The next layer of charge with delayed detonation is blasted again at a certain distance below the upper blasting pit 94 to form a lower blasting pit 95, so that the V-shaped pit is formed by one-time ignition and quick blasting.

Because the time-delay blasting is carried out in the rock prefabricated blast hole, detonation waves generated when the upper charge is blasted are downwards spread along with the hard hole wall, the lower charge is directly induced to be blasted when the detonation waves are propped against the lower charge, and in addition, in order to achieve the best effect, hundreds of milliseconds are required to be delayed after the upper charge is blasted, so that the detonation of the lower charge becomes the technical problem faced by the invention.

The traditional explosion mode also has a scheme of intermittent explosion in the upper and lower explosive column explosion. For example, an explosion-proof material is arranged between two explosion devices to perform explosion isolation, and the explosion-proof material generally only plays a role of blocking shock waves, so that the explosion delay between an upper charging unit and a lower charging unit can not be accurately controlled in explosion, and the requirement of providing a free surface for lower charging by upper charging is met; secondly, the invention needs to ensure the shape and the size of the V-shaped pit, and a blast hole with the diameter slightly larger than that of the blasting device is drilled on hard rock in advance, so that the whole two-stage blasting is carried out in a rock hole of a closed space, and the lower explosive is detonated by the detonation shock wave energy of the upper layer at the same time when in blasting, so that the effect of delay blasting cannot be achieved. Only by overcoming the problems, the rapid forming of the V-shaped pits on the hard rock can be finally realized.

As shown in fig. 4, the rock blasting apparatus of the present invention includes a detonation module 21, an upper grain unit 22, a detonating tube 23, and a lower grain unit 24, which are sequentially disposed from top to bottom; after the detonation assembly 21 detonates, the upper explosive column unit 22 detonates the upper layer rock Dan Di once, and after a period of time is delayed by the explosion isolation tube 23 detonates the lower explosive column unit 24 to perform secondary explosion on the lower layer rock, so that a special V-shaped pit meeting the size requirement is formed.

As shown in fig. 4 and 5, the upper grain unit 22 includes an upper grain 16 and an upper grain 15 provided inside the upper grain 16, the upper grain 15 being blocked inside the upper grain 16 by a plug 18 of the initiation assembly 21; the upper tube 16 is made of PVC material and is primarily of reduced weight.

The detonation assembly 21 comprises a detonation cap 17, a plug 18 and a sealing cover 20, wherein the detonation cap 17 is used for detonating an upper explosive, and is connected with a detonating cord and a pulling method fire cap in series (not shown in the figure) and is stored separately at ordinary times for safety. The detonating primer 17 is fixed on the plug 18 through a primer connector 19, and the plug 18 is made of plastic and plays a role in plugging the upper explosive column and fixing the primer connector. The uppermost end of the initiation assembly 21 is provided with a flap 20. The flap 20 provides sealing, waterproofing, dust-proofing and protection. The detonator connector 19 ensures that the detonator is quickly plugged into place but cannot be pulled out, and the connection is convenient and quick.

Fig. 6 shows a schematic structure of a lower grain unit 24 of the blasting apparatus of the present invention, the lower grain unit 24 comprising a lower pipe 7 and an internally mounted lower grain 6. The lower tube 7 is made of cold drawn steel, and is used for preventing explosion isolation on one hand and resisting explosion generated when the upper tube is used for resisting the upper tube to generate impact on the lower tube.

Fig. 7 to 10 show the structure of the explosion proof tube of the blasting apparatus of the present invention, the explosion proof tube 23 includes an upper connection terminal 11 and a lower connection terminal 36, and the connection terminals function to connect the upper and lower explosive units 22 and 24 and function to transmit explosion, block and support, etc.

In fig. 7 and 8, the upper connection terminal 11 has a flange structure, and the upper medicine tube 16 of the upper medicine column unit 22 is coupled to the flange structure of the upper connection terminal 11 by screw threads; preferably, the interior of the trailing end of the upper tube 16 is provided with a first metal bulb 41; the first metal bulge tube 41 is provided with an internal thread, which is coupled with an external thread on the flange structure of the upper connection terminal 11.

A first cushion 13 is provided between the upper cartridge 16 and the flange structure. The first buffer pad 13 is of a hollow structure, and the second flexible detonating cord 14 passes through the central through hole 51; an annular groove 52 and a straight groove 53 which is communicated with the annular groove 52 and the central through hole 51 are arranged on the outer side of the first cushion pad 13, and the first flexible detonating cord 12 is arranged in the annular groove 52 and the straight groove 53. The middle part of the first flexible detonating cord 12 is wound in the annular groove 52, and both ends are arranged in the straight groove 53.

The detonating cord of fig. 8 includes a core 54 and a sheath 55. The core 54 and sheath 55 of the first flexible detonating cord 12 are in secure contact with the outer sheath of the second flexible detonating cord 14, ensuring secure detonation. The second flexible detonating cord 14 mainly plays a role in explosion propagation, reliably detonates the first flexible detonating cord 12 and the rear partition delay detonator 8, and plugs the first metal expansion tube 41 to prevent the first metal expansion tube from moving downwards after explosion. The first metal expansion tube 41 is used for connecting the upper explosive unit 22 and the upper connecting terminal 11, and is internally provided with a buffer cushion, so that the detonation energy of the upper explosive unit 22 can be effectively attenuated and transmitted downwards. The buffer cushion is made of polyurethane, so that impact and damage caused by detonation of the upper explosive can be attenuated, the safety of the lower-layer medicament and other related components is protected, and the metal connecting terminal is prevented from losing the functions of blocking and supporting due to impact damage.

As shown in fig. 7 and 9, the upper end of the lower connecting terminal 36 is a sleeve 34, an inner sleeve 35 and an outer sleeve 10 are arranged outside the sleeve 34, the inner sleeve 35 and the outer sleeve 10 are made of silicone rubber, and an annular metal expansion tube 9 is arranged between the inner sleeve 35 and the outer sleeve 10. The inner sleeve 35 is of a hollow structure, the second flexible detonating cord 14 passes through the central through hole, a notch 61 is formed in the inner ring of the annular metal expansion tube 9, a straight groove 53 is formed in the positions, corresponding to the notch 61, of the inner sleeve 35 and the sleeve 34, the fourth flexible detonating cord 44 is arranged in the annular metal expansion tube 9, the fourth flexible detonating cord 44 is coiled in the tube of the annular metal expansion tube 9 and the straight groove 53, and the fourth flexible detonating cord 44 is reliably contacted with the second flexible detonating cord 14, so that reliable detonation is ensured. In addition, the inside of the annular metal expansion pipe 9 is filled with explosive filler 45, the explosive filler 45 is made of explosive, and can be detonated by the detonating cord 44, so that an acting force is generated on the annular metal expansion pipe 9 during explosion, the annular metal expansion pipe 9 is radially expanded, the annular metal expansion pipe 9 is embedded in the outer sleeve 10 made of silicon rubber, the outer diameter expansion of the sleeve after explosion is increased, the sleeve is tightly attached to the wall of a rock hole for blocking, and meanwhile, after the explosive filler 45 in the inner part is exploded, the explosive filler plays a role in blocking detonation waves which are transmitted after the upper explosive unit 22 is exploded, so that detonation energy of the upper explosive unit is prevented from being transmitted downwards, and the lower explosive pipe is caused to be subjected to transitional impact, damage and explosion or top impact. The purpose of the explosive filler 45 is to overcome the defect that the conventional detonating cord has small explosive power and is insufficient to ensure the effective expansion of the annular metal expansion tube 9, ensure that the explosion has enough expansion force and play a role in blocking the damage caused by downward transmission of the upper explosive.

The lower end of the lower connecting terminal 36 is a flange 33, and the lower medicine tube 7 of the lower medicine column unit 24 is connected to the flange 33 through threads; a second buffer cushion 31 is arranged between the lower explosive column 6 and the flange 33, the second buffer cushion 31 is of a hollow structure, and a baffle delay detonator 8 is arranged in the hollow part; the partition delay detonator 8 can block the energy of the detonating cord on one hand, and can play a role in starting up and down without influencing the delay time and detonation at the other end of the partition on the other hand.

In fig. 10, the partition board delay detonator 8 is composed of a delay detonator 81, a connecting fire tube 82 and a partition board igniter 83, and the partition board igniter 83 is screwed on the internal thread of the central through hole of the lower connecting terminal 36 through the external thread of the head part and is in butt joint with the second flexible detonating cord 14. The baffle igniter is used for igniting the delay powder of the baffle delay detonator 8 by rotating and burning detonation, so as to realize delayed detonation.

In practice, the second flexible detonating cord 14 is detonated after the explosion impact of the upper explosive column 15, the second flexible detonating cord 14 detonates the explosive at the input ends of the first flexible detonating cord 12, the fourth flexible detonating cord 44 and the partition board igniter 83, and then the explosive is detonated by the explosive of the connecting fire tube 82 to detonate the delay detonator 81, and after the time is delayed for a set time, the lower explosive column 6 is detonated. The baffle delay detonator 8 adopts the conventional prior art, the delay time can be customized by products to ensure the time length precision, and the delay time of the baffle delay detonator 8 in the project is about 500 milliseconds.

The whole blasting device of the invention is assembled and detonated as follows: before use, the detonation component 21 is mounted on the upper explosive tube 16, the upper explosive tube 16 is screwed with the upper connecting terminal 11, the lower explosive tube 7 of the lower explosive column unit 24 is screwed with the lower connecting terminal 36, the two ends of a blast hole are plugged, a detonator wire is taken out, the detonation wire is connected, the wire length is not less than 100 meters, the wire is pulled to a safe position, a special detonator is connected, and the detonation is performed under the condition that personnel and equipment are not needed in the detonation site.

The following describes the design of the blasting device and the principle of one shot blasting forming of V-shaped pits.

V-shaped pit requirement

As shown in FIG. 1, the V-shaped pit is of an inverted cone structure, the depth of the pit body is not less than 110 cm, the bottom width is 50 cm, and the caliber is not less than 65 cm. Basically is a cone with wide upper part and narrow lower part, and can be also called as a variable type blasting funnel; no concave-convex and unstable rock exists in the explosion pit after explosion, and meanwhile, the rock blocks in the pit are convenient for manual cleaning.

(II) parameter design

The parameters of the whole blasting device are as follows: the upper charge tube is made of PVC material and has the size of

The upper charge is 1.01 kg, and the weight of the part is less than 1.5kg; the explosion isolation tube is made of expansion material, and the size is smaller than +.>

Weight is less than 1.2kg; the lower charge tube is made of A3 steel with better ductility, and the size is smaller than +.>

The lower charge was 1.2kg and the part weight was less than 2.0kg. The flameproof delay time of the upper and lower medicine pipes is not less than 500ms.

(III) one-step Forming principle of V-shaped pit

The explosion principle of the explosion device of the invention is as follows:

【1】 Firstly, drilling a prefabricated hole with the diameter slightly larger than that of a medicine tube on rock by adopting a hand-held drilling machine, and then placing the assembled blasting device in the hole;

【2】 The blasting cap 17 is ignited to cause the upper explosive 15 to explode, so as to carry out the first blasting on the rock;

【3】 The detonating primer 17 triggers the second flexible detonating cord 14 to detonate or triggers the second flexible detonating cord 14 to detonate after the upper explosive column 15 explodes;

【4】 After the second flexible detonating cord 14 is detonated, the first flexible detonating cord 12 is initiated to detonate, the first metal expansion tube 41 is expanded, and the first buffer pad 13 and the first metal expansion tube 41 perform combined action to buffer and block primary explosion waves;

【5】 The second flexible detonating cord 14 initiates the explosion of the fourth flexible detonating cord 44 and the explosion filler 45 in the cascaded annular metal expansion tube 9, and the primary explosion wave is buffered and blocked again under the combined action of the inner sleeve 35, the outer sleeve 10, the upper connecting terminal 11, the lower connecting terminal 36, the second buffer pad 31 and the annular metal expansion tube 9;

【6】 The second flexible detonating cord 14 triggers the diaphragm delay detonator 8, and after hundreds of milliseconds, the diaphragm delay detonator 8 triggers the lower explosive column 6 to detonate, and secondary blasting is carried out on the rock to form a V-shaped pit.

The invention can implement one-time blasting forming with depth more than 1.1 meter on hard rock, and can also be used for blasting forming of other special pits on the rock.

Claims (7)

1. The utility model provides a sealed space segmentation separate charge detonation isolation tube which characterized in that: comprises an upper connecting terminal (11) and a lower connecting terminal (36) which are movably connected through threads;

the upper connecting terminal (11) is of a flange structure, and an upper medicine tube (16) of the upper medicine column unit (22) is connected to the flange structure of the upper connecting terminal (11) through threads; a first buffer pad (13) is arranged between the upper medicine tube (16) and the flange structure; the first buffer pad (13) is of a hollow structure, and a second flexible detonating cord (14) is arranged in the central through hole (51) of the first buffer pad; an annular groove (52) and a straight groove (53) which is communicated with the annular groove (52) and the central through hole (51) are formed in the outer side of the first buffer pad (13), and a first flexible detonating cord (12) is arranged in the annular groove (52) and the straight groove (53); the first flexible detonating cord (12) is contacted with the second flexible detonating cord (14);

the upper end of the lower connecting terminal (36) is provided with a sleeve (34), an inner sleeve (35) and an outer sleeve (10) are arranged outside the sleeve (34), a plurality of cascaded annular metal expansion pipes (9) are arranged between the inner sleeve (35) and the outer sleeve (10), the lower end of the lower connecting terminal (36) is provided with a flange (33), and a lower medicine pipe (7) of the lower medicine column unit (24) is connected to the flange (33) through threads; a lower layer of grains (6) is arranged in the lower medicine tube (7), and a second buffer cushion (31) is arranged between the lower layer of grains (6) and the flange (33) in the lower medicine tube (7); the inner sleeve (35) and the outer sleeve (10) are made of silicon rubber; the upper explosive column (15) and the lower explosive column (6) are TNT explosives.

2. The closed space-section-separated-charge detonation-isolation tube of claim 1, wherein: the inner ring of the annular metal expansion pipe (9) is provided with a notch (61), the positions of the inner sleeve (35) and the sleeve (34) corresponding to the notch (61) are provided with straight grooves (53), a fourth flexible detonating cord (44) is arranged in the annular metal expansion pipe (9), and the fourth flexible detonating cord (44) is coiled in the pipe of the annular metal expansion pipe (9) and the straight grooves (53) and is in contact with the second flexible detonating cord (14).

3. The closed space-section-separated-charge detonation-isolation tube of claim 2, wherein: the annular metal expansion pipe (9) is filled with explosive.

4. The closed space-section-separated-charge detonation-isolation tube of claim 2, wherein: the number of the annular metal expansion pipes (9) is two.

5. The closed space-section-separated-charge detonation-isolation tube of claim 1, wherein: a first metal expansion tube (41) is arranged in the tail end of the upper medicine tube (16); the first metal expansion pipe (41) is provided with internal threads and is connected with external threads on the flange structure of the upper connecting terminal (11).

6. The closed space-section-separated-charge detonation-isolation tube of claim 1, wherein: the lower explosive column unit (24) comprises a lower explosive tube (7) and a bottom cover (1), and the lower explosive column (6) is blocked inside the lower explosive tube (7) by the bottom cover (1).

7. Method for explosion suppression using a detonation isolation tube for closed space segment-wise spaced charges according to any of claims 1-6, characterized by the steps of:

【1】 Arranging a segmented spaced charge detonation isolation tube in the closed space;

【2】 The upper explosive column (15) explodes to trigger the second flexible detonating cord (14) to detonate;

【3】 After the second flexible detonating cord (14) detonates, the first flexible detonating cord (12) is initiated, the first metal expanded tube (41) is expanded, the first buffer pad (13) and the first metal expanded tube (41) act comprehensively, and the first explosion wave is buffered and blocked;

【4】 The second flexible detonating cord (14) triggers the fourth flexible detonating cord (44) and the explosion filler (45) in the cascaded annular metal expansion tube (9) to explode, and the combined action of the inner sleeve (35), the outer sleeve (10), the upper connecting terminal (11), the lower connecting terminal (36), the second buffer pad (31) and the annular metal expansion tube (9) buffers and blocks the primary explosion wave again to prevent the lower explosive column (6) from being subjected to the sympathetic explosion.

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