CN112945033A - Explosion-proof cable water resistance performance detection device - Google Patents

Abstract

The invention relates to a detection device, in particular to a water resistance detection device for an explosion wire. The invention provides a water resistance detection device for detonating cords, which can test detonating cords of different varieties and is accurate in test. The invention provides a water resistance detection device for an explosion wire, which comprises: the bottom plate is provided with a frame body; the frame body is provided with a moving device; the clamping device is arranged on the moving device. One ends of detonating cords of different varieties are fixed through the clamping device, the moving device moves leftwards to drive the clamping device to move leftwards to the top of the frame body, and the moving device rotates downwards to drive the clamping device to rotate downwards to soak the detonating cords in water for water resistance detection.

Description

Explosion-proof cable water resistance performance detection device

Technical Field

The invention relates to a detection device, in particular to a water resistance detection device for an explosion wire.

Background

The detonating cord is a linear igniter for simultaneously detonating a plurality of explosive charges or explosive blocks, and is commonly used in presplitting blasting and smooth blasting construction, wherein a detonating cord network outside a blast hole is generally laid. When underwater blasting is carried out, a plastic detonating cord is generally used for detonating explosives, and the conventional plastic detonating cord is transported to the site for use after the manufacturer finishes production.

The general detection mode is that manual detection is performed, the manual detection may have the phenomenon of inaccurate detection, which results in unqualified quality of the plastic detonating cord, and when the plastic detonating cord is used under the conditions of high water pressure and deep water depth, the end part of the detonating cord is soaked in water, so that the original effect is easily lost, the detonation effect of the plastic detonating cord detonating explosive is affected, the safety blasting of the explosive is affected, the explosive cannot explode underwater according to the preset requirement, and potential safety hazards are generated.

Therefore, it is highly desirable to design a water resistance testing apparatus for detonating cords, which can test water resistance of different types of detonating cords accurately, and is used to solve the above problems.

Disclosure of Invention

In order to overcome the defects that the end part of an explosion fuse is easy to lose the original effect after being soaked in water, the detonation effect of a plastic explosion fuse detonating explosive is influenced, the explosive can not explode underwater according to the preset requirement, and the potential safety hazard is generated, the technical problems are as follows: the explosion-proof cable water resistance performance detection device can test different varieties of explosion-proof cables and is accurate in test.

The technical scheme is as follows: a water resistance performance detection device for a detonating cord comprises: the bottom plate is provided with a frame body; the frame body is provided with a moving device; the clamping device is arranged on the moving device.

Optionally, the mobile device comprises: the two sides of the frame body are provided with the sliding groove plates; the two sliding groove plates are internally provided with sliding blocks in a sliding manner; the round rotating shaft is rotatably arranged between the two sliding blocks, and two ends of the round rotating shaft penetrate through the two sliding blocks; the first handle, the slider lateral wall of one side is provided with first handle.

Optionally, the clamping means comprises: four wire guiding wheels are uniformly arranged on the circular rotating shaft at intervals; the four guide wheels are positioned in the four rotating blocks; one end of each of the four rotating blocks is provided with a first fixed block; two sides of each of the four first fixing blocks are provided with a first sliding rod in a sliding manner; the second handle is arranged between the tops of two adjacent first sliding rods; the fixed rods are arranged at the center positions of the bottoms of the four second handles; and first elastic pieces are arranged between one side of the first sliding rod and the side wall of the first fixed block.

Optionally, the method further comprises: the first bearing seat is arranged on one side of the bottom plate; the first rotating shaft sleeve is rotatably arranged on the first bearing block; the first rotating shaft sleeve is provided with a placing rod; the second elastic piece is arranged between one side of the first rotating shaft sleeve and one side of the first bearing seat; the other side of the bottom plate is provided with a second fixed block; the top of the second fixed block is rotatably provided with a second bearing seat; the top of the second bearing seat is rotatably provided with a second rotating shaft sleeve, and the other end of the placing rod is connected with the second rotating shaft sleeve; the clamping sleeve is arranged on the side wall of the second fixed block; the guide sleeve is arranged on the side wall of the second bearing seat; the guide sleeve is internally provided with a second sliding rod in a sliding manner; and a third elastic piece is arranged between one side of the second sliding rod and one side of the guide sleeve.

Optionally, the method further comprises: limiting plates are arranged on the opposite sides of the two chute plates; the two sides of the round rotating shaft are provided with swing rods, and the two swing rods are matched with the two limiting plates; the fourth elastic piece is arranged between one side of each of the two oscillating rods and one side of each of the two sliding blocks; the gears are arranged at the two ends of the round rotating shaft; and the two sides of the two chute plates, back to the side, are provided with racks, and the two gears are matched with the racks.

Optionally, the method further comprises: a third slide bar is arranged between one sides of the two chute plates in a sliding manner; a fifth elastic piece is arranged between the two ends of the third sliding rod and one side of the two chute plates; the blades and the third sliding rod are evenly provided with four blades at intervals.

Optionally, the method further comprises: the tops of the two sliding blocks are provided with third fixed blocks; the fixing frames are arranged on the sides, back to the two third fixing blocks, of the two third fixing blocks; the end parts of the two fixing frames are rotatably provided with wedge blocks through supporting rods, and the two wedge blocks are matched with the two ends of the third sliding rod; the sixth elastic piece is arranged between one side of each wedge-shaped block and one side of each fixing frame; the limiting rods are arranged at the bottoms of the two fixing frames.

Optionally, the method further comprises: four flame throwers are uniformly arranged on one side of the bottom plate at intervals; the switches are arranged at the bottoms of the four flame throwers; the bottom plate on the same side is uniformly provided with fourth sliding rods in a sliding mode at intervals, and the four switches are connected with the four fourth sliding rods; and a third handle is arranged between the tops of the four fourth sliding rods.

The invention has the following advantages: 1. one ends of detonating cords of different varieties are fixed through the clamping device, the moving device moves leftwards to drive the clamping device to move leftwards to the top of the frame body, and the moving device rotates downwards to drive the clamping device to rotate downwards to soak the detonating cords in water for water resistance detection.

2. The dead lever removes down and can fixes the detonating cord, drops when avoiding soaking in water.

3. The explosion wire coils of four different varieties can be placed by the placing rod, so that the explosion wire coils can be clamped on the first fixing block by a worker conveniently, and water resistance detection is performed.

4. The flame thrower can ignite the detonating cord with water, and then tests out which type detonating cord has strong waterproofness.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic perspective view of a mobile device according to the present invention.

Fig. 3 is a schematic perspective view of the chucking device of the present invention.

FIG. 4 is a schematic view of a first partial body structure according to the present invention.

FIG. 5 is a schematic view of a second partial body structure according to the present invention.

Fig. 6 is a perspective view of a third embodiment of the present invention.

Fig. 7 is a perspective view of a fourth embodiment of the present invention.

FIG. 8 is a schematic view of a fifth partial body structure according to the present invention.

Fig. 9 is a schematic view of a sixth partial body structure according to the present invention.

The meaning of the reference symbols in the figures: 1: bottom plate, 2: frame, 3: moving device, 31: chute plate, 32: slider, 33: circular rotating shaft, 34: first handle, 4: chucking device, 41: wire guide wheel, 42: turning block, 43: first fixing block, 44: first slide bar, 45: second handle, 46: fixing rod, 47: first elastic member, 5: first bearing seat, 6: first hub sleeve, 7: placing rod, 8: second elastic member, 9: second fixed block, 10: second bearing housing, 11: second spindle sleeve, 12: cutting ferrule, 13: guide sleeve, 14: second slide bar, 15: third elastic member, 16: a limiting plate, 17: swing lever, 18: fourth elastic member, 19: gear, 20: rack, 21: third slide bar, 22: fifth elastic member, 23: blade, 24: third fixed block, 25: mount, 26: wedge block, 27: sixth elastic member, 28: stop lever, 29: flame thrower, 30: switch, 301: a fourth slide bar, 302: and a third handle.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings. It is only noted that the invention is intended to be limited to the specific forms set forth herein, including any reference to the drawings, as well as any other specific forms of embodiments of the invention.

Example 1

As shown in fig. 1, the water resistance detection device for the detonating cord comprises a bottom plate 1, a frame body 2, a moving device 3 and a clamping device 4, wherein the frame body 2 is arranged on the bottom plate 1, the moving device 3 is arranged on the frame body 2, and the clamping device 4 is arranged on the moving device 3.

When the water resistance performance of different types of detonating cords needs to be detected, a worker adds a certain amount of water into the frame body 2, pulls the clamping device 4 by the worker, the clamping device 4 moves upwards, then places one end of the different types of detonating cords on the clamping device 4 by the worker, then loosens the clamping device 4, the clamping device 4 moves downwards and resets to fix the detonating cords, after the fixation is completed, the worker moves the moving device 3 leftwards, the moving device 3 moves leftwards to drive the clamping device 4 to move leftwards to the top of the frame body 2, then the worker rotates the moving device 3, the moving device 3 rotates to drive the clamping device 4 to rotate downwards to soak the detonating cords in the water for the water resistance performance detection, after the detonating cords are soaked for a certain time, the worker rotates the moving device 3, the moving device 3 rotates to drive the clamping device 4 to rotate upwards and reset, at the moment, the operator moves the moving device 3 to the right to reset, and the moving device 3 moves to the right to drive the clamping device 4 to move to reset to the right. The device has simple structure and convenient operation.

Example 2

As shown in fig. 2 and 3, based on embodiment 1, the moving device 3 includes a chute plate 31, sliders 32, a circular rotating shaft 33 and a first handle 34, the chute plate 31 is disposed on both front and rear sides of the frame 2, the sliders 32 are slidably disposed in both the chute plates 31, the circular rotating shaft 33 is rotatably disposed between the two sliders 32, both front and rear ends of the circular rotating shaft 33 penetrate through the two sliders 32, and the first handle 34 is disposed on a side wall of the slider 32 on the front side.

After a certain amount of water is added into the frame body 2, a worker places one end of each detonating cord of different types on the clamping device 4, fixes one end of the detonating cord through the clamping device 4, after the fixation is finished, the worker moves the first handle 34 leftwards, the first handle 34 moves leftwards to drive the front slide block 32 to slide leftwards in the front sliding groove plate 31, the front slide block 32 slides leftwards to drive the rear slide block 32 to slide leftwards in the rear sliding groove plate 31 through the rotating shaft 33, the rotating shaft 33 moves leftwards to drive the clamping device 4 to move leftwards to the top of the frame body 2, at the moment, the worker rotates the rotating shaft 33, the rotating shaft 33 rotates to drive the clamping device 4 to rotate downwards to soak the detonating cord in the water for water resistance detection, after the detonating cord is soaked for a certain time, the worker reverses the rotating shaft 33, the rotating shaft 33 reverses to drive the clamping device 4 to rotate upwards for resetting, at this time, the worker moves the first handle 34 to the right, the first handle 34 moves to the right to drive the front sliding block 32 to slide and reset to the right in the front sliding groove plate 31, the front sliding block 32 slides to the right to drive the rear sliding block 32 to slide and reset to the right in the rear sliding groove plate 31 through the circular rotating shaft 33, and the circular rotating shaft 33 moves to the right to drive the clamping device 4 to move and reset to the right. The device has simple structure, and can drive the clamping device 4 to rotate so as to soak the detonating cord in water for water resistance detection.

Chucking device 4 is including wire wheel 41, turning block 42, first fixed block 43, first slide bar 44, second handle 45, dead lever 46 and first elastic component 47, even interval is provided with four wire wheels 41 on the round pivot 33, even interval is provided with four turning blocks 42 on the round pivot 33, four wire wheels 41 are located four turning blocks 42, four turning block 42 right-hand members all are provided with first fixed block 43, four first fixed block 43 front and back both sides all slidingtype are provided with first slide bar 44, all be provided with second handle 45 between two close first slide bar 44 tops, four second handle 45 bottom central point put all is provided with dead lever 46, all be provided with first elastic component 47 between first slide bar 44 one side and the first fixed block 43 lateral wall.

When a certain amount of water is added into the frame body 2, a worker pulls the second handle 45 to move upwards, the second handle 45 moves upwards to drive the first slide rod 44 to slide upwards on the first fixing block 43, the first elastic piece 47 is compressed, the worker places one end of each detonating cord of different types on the first fixing block 43 by bypassing the wire guide wheel 41, then the worker releases the second handle 45, the first elastic piece 47 resets to drive the first slide rod 44 to slide downwards on the first fixing block 43 for resetting, the first slide rod 44 slides downwards to drive the second handle 45 to move downwards, the fixing rod 46 moves downwards to fix the detonating cord, when the circular rotating shaft 33 moves leftwards to drive the wire guide wheel 41 and the rotating block 42 to move leftwards, and when the wire guide wheel 41 and the rotating block 42 move leftwards to the top of the frame body 2, the worker rotates the circular rotating shaft 33, the circular rotating shaft 33 rotates to drive the rotating block 42 to rotate downwards, the rotating block 42 rotates downwards to enable the detonating cord to be soaked in water for water resistance detection, after the detonating cord is soaked for a certain time, a worker rotates the circular rotating shaft 33, the circular rotating shaft 33 rotates to drive the rotating block 42 to rotate upwards for resetting, and the circular rotating shaft 33 moves rightwards to drive the wire guide wheel 41 and the rotating block 42 to move rightwards for resetting. This device simple structure can fix the detonating cord, avoids dropping when soaking in water.

Example 3

As shown in fig. 4, 5, 6, 7, 8 and 9, the present invention further comprises a first bearing seat 5, a first rotating shaft sleeve 6, a placing rod 7, a second elastic member 8, a second fixed block 9, a second bearing seat 10, a second rotating shaft sleeve 11, a clamping sleeve 12, a guide sleeve 13, a second sliding rod 14 and a third elastic member 15, the first bearing seat 5 is disposed on the right side of the rear portion of the base plate 1, the first rotating shaft sleeve 6 is rotatably disposed on the first bearing seat 5, the placing rod 7 is disposed on the first rotating shaft sleeve 6, the second elastic member 8 is disposed between one side of the first rotating shaft sleeve 6 and one side of the first bearing seat 5, the second fixed block 9 is disposed on the right side of the front portion of the base plate 1, the second bearing seat 10 is rotatably disposed on the top of the second fixed block 9, the second rotating shaft sleeve 11 is rotatably disposed on the top of the second bearing seat 10, the front end of the placing rod 7 is connected with, a guide sleeve 13 is arranged on the rear side wall of the second bearing seat 10, a second slide bar 14 is arranged in the guide sleeve 13 in a sliding manner, and a third elastic piece 15 is arranged between one side of the second slide bar 14 and one side of the guide sleeve 13.

When the water resistance performance of different types of detonating cords is required to be detected, a worker pulls the second slide rod 14, the second slide rod 14 slides rightwards on the guide sleeve 13 without clamping the clamping sleeve 12, the third elastic piece 15 is stretched, then the worker rotates the second bearing seat 10 downwards, the second bearing seat 10 rotates downwards to drive the second rotating shaft sleeve 11 to move downwards to be separated from the front end of the placing rod 7, at the moment, the worker places four detonating cord coils of different types on the placing rod 7, after the placing is completed, the worker rotates the second bearing seat 10 upwards, the second bearing seat 10 rotates upwards to drive the second rotating shaft sleeve 11 to move upwards to clamp the front end of the placing rod 7, at the moment, the worker loosens the second slide rod 14, the third elastic piece 15 resets to drive the second slide rod 14 to slide leftwards on the guide sleeve 13 to clamp the clamping sleeve 12, and when the circular rotating shaft 33 moves leftwards to drive the detonating cord to move leftwards, the detonating cord moves left and drives placing rod 7 to rotate, placing rod 7 rotates and drives first rotating shaft sleeve 6 and second rotating shaft sleeve 11 to rotate, second elastic piece 8 deforms, when circular rotating shaft 33 moves right, second elastic piece 8 resets and drives first rotating shaft sleeve 6 to rotate, first rotating shaft sleeve 6 rotates and drives placing rod 7 to rotate, placing rod 7 rotates and drives second rotating shaft sleeve 11 to rotate and place rod 7 to rotate and drive detonating cord coil to rotate, and then tensioning detonating cord. This device simple structure can place the detonating cord coil of four different varieties, makes things convenient for the staff more to block detonating cord one end on first fixed block 43, carries out water resistance performance and detects.

Still include limiting plate 16, swinging arms 17, fourth elastic component 18, gear 19 and rack 20, two chute board 31 all are provided with limiting plate 16 in one side in opposite directions, both sides all are provided with swinging arms 17 around the round pivot 33, two swinging arms 17 and two limiting plate 16 cooperations, all be provided with fourth elastic component 18 between two swinging arms 17 one side and two slider 32 one sides, both ends all are provided with gear 19 around the round pivot 33, two chute board 31 all are provided with rack 20 in one side dorsad, two gear 19 and rack 20 mutually support.

When the worker moves the first handle 34 leftwards to drive the sliding block 32 to slide leftwards to the middle of the frame body 2 in the chute plate 31, the gear 19 moves leftwards to be meshed with the rack 20, the gear 19 rotates to drive the circular rotating shaft 33 to rotate, the circular rotating shaft 33 rotates to drive the swinging rod 17 to rotate downwards, the fourth elastic element 18 deforms, the swinging rod 17 rotates downwards to not push against the limiting plate 16 any more, the circular rotating shaft 33 rotates to drive the rotating block 42 to rotate downwards, the rotating block 42 rotates downwards to enable the detonating cord to be soaked in water, after the detonating cord is soaked for a certain time, the worker moves the first handle 34 rightwards to drive the sliding block 32 to slide rightwards in the chute plate 31 to reset, the gear 19 moves rightwards to be meshed with the rack 20, the gear 19 rotates to drive the circular rotating shaft 33 to rotate, the circular rotating shaft 33 rotates to drive the swinging rod 17 to rotate upwards, the fourth elastic element 18 resets, and the swinging rod 17 rotates upwards to, the rotation of the rotary shaft 33 drives the rotary block 42 to rotate upwards for resetting. The device has simple structure, can automatically rotate the round rotating shaft 33, and does not need to be manually rotated any more.

The novel cutting machine is characterized by further comprising a third sliding rod 21, a fifth elastic piece 22 and blades 23, the third sliding rod 21 is arranged between the right sides of the two sliding groove plates 31 in a sliding mode, the fifth elastic piece 22 is arranged between the two ends of the third sliding rod 21 and one side of each of the two sliding groove plates 31, and the four blades 23 are evenly arranged on the third sliding rod 21 at intervals.

After the round rotating shaft 33 moves rightwards to drive the clamping device 4 to move rightwards and reset, a worker presses the third sliding rod 21 to slide downwards in the sliding chute plate 31, the fifth elastic piece 22 is compressed, the third sliding rod 21 slides downwards to drive the blade 23 to move downwards to cut the end part of the soaked and scattered detonating cord, after the cutting is finished, the worker loosens the third sliding rod 21, the fifth elastic piece 22 resets to drive the third sliding rod 21 to slide upwards in the sliding chute plate 31 to reset, and the third sliding rod 21 slides upwards to drive the blade 23 to move upwards to reset. This device simple structure can cut the detonating fuse tip that soaks the scattering.

Still including third fixed block 24, mount 25, wedge 26, sixth elastic component 27 and gag lever post 28, two slider 32 tops all are provided with third fixed block 24, two third fixed blocks 24 all are provided with mount 25 to one side dorsad, two mount 25 tip all are provided with wedge 26 through the branch rotary type, both ends cooperation around two wedges 26 and the third slide bar 21, all be provided with sixth elastic component 27 between two wedge 26 one sides and two mount 25 one sides, two mount 25 bottoms all are provided with gag lever post 28.

When the sliding block 32 slides leftwards in the chute plate 31, the sliding block 32 slides leftwards to drive the third fixed block 24 to move leftwards, the third fixed block 24 moves leftwards through the fixed frame 25 to drive the wedge block 26 to move leftwards and is contacted with the end part of the third sliding rod 21, the wedge block 26 rotates upwards on the fixed frame 25, the sixth elastic element 27 deforms, when the wedge block 26 moves leftwards and is not contacted with the end part of the third sliding rod 21, the sixth elastic element 27 resets to drive the wedge block 26 to rotate downwards on the fixed frame 25 for resetting, when the sliding block 32 slides rightwards in the chute plate 31 for resetting, the sliding block 32 slides rightwards to drive the third fixed block 24 to move rightwards, the third fixed block 24 moves rightwards to drive the wedge block 26 to move rightwards through the fixed frame 25 to be contacted with the end part of the third sliding rod 21 and presses the third sliding rod 21 downwards, the third sliding rod 21 slides downwards in the chute plate 31, and the fifth elastic element, when the third sliding rod 21 slides downwards to drive the blade 23 to move downwards to cut the end part of the soaked detonating cord, and the wedge block 26 moves rightwards and is not contacted with the third sliding rod 21 any more, the fifth elastic piece 22 resets to drive the third sliding rod 21 to slide upwards and reset in the sliding chute plate 31, and the third sliding rod 21 slides upwards to drive the blade 23 to move upwards and reset. The device is simple in structure, and can drive the blade 23 to move downwards to cut the end part of the soaked and scattered detonating cord while the sliding block 32 is reset.

The four-bar flame-retardant plastic base plate is characterized by further comprising flame throwers 29, switches 30, fourth sliding bars 301 and third handles 302, wherein the four flame throwers 29 are uniformly arranged on the right side of the base plate 1 at intervals, the switches 30 are arranged at the bottoms of the four flame throwers 29, the fourth sliding bars 301 are slidably arranged on the base plate 1 on the same side at intervals, the four switches 30 are connected with the four fourth sliding bars 301, and the third handles 302 are arranged between the tops of the four fourth sliding bars 301.

After the cutting of the blasting fuse is completed, a worker presses the third handle 302 to move downwards, the third handle 302 moves downwards to drive the fourth slide bar 301 to slide downwards on the bottom plate 1, the fourth slide bar 301 slides downwards to press the switch 30 to open the flame thrower 29, the flame thrower 29 ignites the blasting fuse with water, the water resistance performance of different types of blasting fuses can be detected, after the blasting fuse is detected to be completed, the worker controls the third handle 302 to move upwards, the third handle 302 moves upwards to drive the fourth slide bar 301 to slide upwards on the bottom plate 1, and the fourth slide bar 301 slides upwards to press the switch 30 to close the flame thrower 29. This device simple structure can ignite the detonating cord of bubble water, and then tests out that the detonating cord waterproof nature of which variety is strong.

While the disclosure has been shown and described with reference to certain exemplary embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the disclosure as defined by the appended claims and their equivalents. Accordingly, the scope of the present disclosure should not be limited to the above-described embodiments, but should be defined not only by the appended claims, but also by equivalents thereof.

Claims (8)

1. The utility model provides a water resistance capability detection device of explosion wire which characterized in that includes:

the device comprises a bottom plate (1), wherein a frame body (2) is arranged on the bottom plate (1);

the moving device (3) is arranged on the frame body (2);

the clamping device (4) is arranged on the moving device (3).

2. The explosion wire water-resistant performance detection device as claimed in claim 1, wherein the moving device (3) comprises:

the sliding groove plates (31) are arranged on the two sides of the frame body (2);

the sliding blocks (32) are arranged in the two sliding groove plates (31) in a sliding manner;

a circular rotating shaft (33), wherein the circular rotating shaft (33) is rotatably arranged between the two sliding blocks (32), and two ends of the circular rotating shaft (33) penetrate through the two sliding blocks (32);

the first handle (34) is arranged on the side wall of the sliding block (32) on one side of the first handle (34).

3. The explosion wire water-resistant performance detection device as claimed in claim 2, wherein the clamping device (4) comprises:

four wire guiding wheels (41) are uniformly arranged on the round rotating shaft (33) at intervals;

the wire guide device comprises rotating blocks (42), wherein four rotating blocks (42) are uniformly arranged on a circular rotating shaft (33) at intervals, and four wire guide wheels (41) are positioned in the four rotating blocks (42);

one end of each of the four rotating blocks (42) is provided with a first fixed block (43);

the two sides of the four first fixed blocks (43) are provided with first sliding rods (44) in a sliding manner;

the second handles (45) are arranged between the tops of the two adjacent first sliding rods (44);

the fixing rods (46) are arranged at the center positions of the bottoms of the four second handles (45);

and a first elastic element (47) is arranged between one side of the first sliding rod (44) and the side wall of the first fixed block (43).

4. The explosion wire water-resistant performance detection device of claim 3, further comprising:

the bearing device comprises a first bearing seat (5), wherein the first bearing seat (5) is arranged on one side of a bottom plate (1);

the first rotating shaft sleeve (6) is rotatably arranged on the first bearing seat (5);

a placing rod (7), wherein the placing rod (7) is arranged on the first rotating shaft sleeve (6);

a second elastic piece (8), wherein the second elastic piece (8) is arranged between one side of the first rotating shaft sleeve (6) and one side of the first bearing seat (5);

a second fixed block (9), wherein the other side of the bottom plate (1) is provided with the second fixed block (9);

the top of the second fixed block (9) is rotatably provided with a second bearing seat (10);

the top of the second bearing seat (10) is rotatably provided with a second rotating shaft sleeve (11), and the other end of the placing rod (7) is connected with the second rotating shaft sleeve (11);

the side wall of the second fixing block (9) is provided with a clamping sleeve (12);

the guide sleeve (13) is arranged on the side wall of the second bearing seat (10);

the second sliding rod (14) is arranged in the guide sleeve (13) in a sliding manner;

and a third elastic piece (15) is arranged between one side of the second sliding rod (14) and one side of the guide sleeve (13).

5. The explosion wire water-resistant performance detection device of claim 4, further comprising:

the limiting plates (16) are arranged on the opposite sides of the two chute plates (31);

the two sides of the round rotating shaft (33) are provided with the swinging rods (17), and the two swinging rods (17) are matched with the two limiting plates (16);

a fourth elastic piece (18), wherein the fourth elastic piece (18) is arranged between one side of each of the two swinging rods (17) and one side of each of the two sliding blocks (32);

the gear (19) is arranged at both ends of the round rotating shaft (33);

the two sides of the two chute plates (31) back to each other are provided with racks (20), and the two gears (19) are matched with the racks (20).

6. The explosion wire water-resistant performance detection device of claim 5, further comprising:

a third slide bar (21), wherein the third slide bar (21) is arranged between one sides of the two chute plates (31) in a sliding way;

a fifth elastic piece (22) is arranged between the two ends of the third sliding rod (21) and one side of the two chute plates (31);

the blade (23) and the third sliding rod (21) are provided with four blades (23) at uniform intervals.

7. The explosion wire water-resistant performance detection device of claim 6, further comprising:

the tops of the two sliding blocks (32) are provided with the third fixed block (24);

the fixing frames (25) are arranged on the two third fixing blocks (24) at the back sides;

the end parts of the two fixing frames (25) are respectively provided with a wedge-shaped block (26) in a rotating mode through a supporting rod, and the two wedge-shaped blocks (26) are matched with the two ends of the third sliding rod (21);

sixth elastic pieces (27), and the sixth elastic pieces (27) are arranged between one side of each of the two wedge-shaped blocks (26) and one side of each of the two fixing frames (25);

the limiting rods (28) are arranged at the bottoms of the two fixing frames (25).

8. The explosion wire water-resistant performance detection device of claim 7, further comprising:

four flame throwers (29) are uniformly arranged on one side of the bottom plate (1) at intervals;

the switches (30) are arranged at the bottoms of the four flame throwers (29);

the fourth sliding rods (301) are uniformly arranged on the bottom plate (1) on the same side at intervals in a sliding mode, and the four switches (30) are connected with the four fourth sliding rods (301);

and a third handle (302) is arranged between the tops of the four fourth sliding rods (301).

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