CN218148826U - Deep hole accumulated water discharge device - Google Patents

Abstract

The utility model belongs to the technical field of drainage device and specifically relates to a deep hole ponding eduction gear is related to, it includes the fixed plate, the preformed hole has been seted up to the fixed plate, fixed surface is connected with first backup pad and second backup pad on the fixed plate, be connected with between first backup pad and the second backup pad and carry the subassembly, it is connected with the suction pump to carry the subassembly, the suction pump is provided with the delivery port, delivery port fixedly connected with hose. This application has the effect that improves deep hole ponding discharge efficiency.

Description

Deep hole accumulated water discharge device

Technical Field

The application relates to the field of drainage devices, in particular to a deep hole accumulated water drainage device.

Background

The current surface mine blasting usually adopts deep hole blasting, and the drilled deep hole has accumulated water in the hole due to the influence of rainfall or rock stratum water seepage, so that the subsequent blasting operation is influenced.

The common deep hole drainage method comprises the steps that simple small barrels are used for draining water, a worker binds and fixes the small barrels through ropes, then the small barrels are placed to the bottom of a hole, after the small barrels are filled with water, the lifting ropes pull the small barrels out of the deep hole, accumulated water is poured out, and then the process is circularly carried out until the accumulated water in the deep hole is completely drained.

In view of the above-described related art, the inventors consider that there is a drawback in that accumulated water discharge efficiency is low.

SUMMERY OF THE UTILITY MODEL

In order to improve the efficiency of deep hole ponding discharge, this application provides a deep hole ponding eduction gear

The application provides a deep hole ponding eduction gear adopts following technical scheme:

the utility model provides a deep hole ponding eduction gear, includes the fixed plate, the preformed hole has been seted up to the fixed plate, fixed surface is connected with first backup pad and second backup pad on the fixed plate, be connected with between first backup pad and the second backup pad and carry the subassembly, it is connected with the suction pump to carry and draws the subassembly, the suction pump is provided with the delivery port, delivery port fixedly connected with hose.

Through adopting above-mentioned technical scheme, when having ponding to need discharge in the deep hole, operating personnel arranges the fixed plate in the deep hole top, then makes the suction pump pass the preformed hole and transfer the suction pump to the deep hole bottom along the deep hole through carrying the lifting unit, and ponding in the deep hole passes through the delivery port through the suction pump effect, upwards discharges to the earth's surface along the hose, compares in self-control small bucket and has improved drainage speed, has the effect that improves the downthehole ponding efficiency of discharge deep hole. When the drainage work is completed, the operating personnel enable the water suction pump to move upwards along the deep hole through the lifting assembly, and after the water suction pump is lifted to leave the deep hole, the operating personnel place the water suction pump on the fixing plate.

Optionally, the lifting assembly comprises a rope winding rod rotatably connected between the first support plate and the second support plate, the rope winding rod is fixedly connected with a lifting rope, the lifting rope is fixedly connected with the water pump, one end of the rope winding rod is fixedly connected with a first lifting rod, and one end of the first lifting rod, which is far away from the rope winding rod, is fixedly connected with a second lifting rod.

Through adopting above-mentioned technical scheme, rotate the second and carry the pull rod, carry the pull rod through first and drive the rope winding pole and rotate, carry the stay cord and leave the rope unwinding pole, the suction pump whereabouts carries out drainage work to the deep hole bottom, and the process of suction pump whereabouts is more convenient.

Optionally, one end of the rope winding rod, which is far away from the first lifting rod, is connected with a locking assembly for fixing the rope winding rod.

Through adopting above-mentioned technical scheme, after drainage work was accomplished, operating personnel made the suction pump promote through rotating the second and carry the pull rod, when not needing the suction pump to move in vertical direction, locking Assembly fixed with the serving pole, reduced the possibility that the suction pump moved along vertical direction.

Optionally, the locking assembly comprises a ratchet fixedly connected with the rope winding rod, the second supporting plate is fixedly connected with a fixing rod, and one end, far away from the second supporting plate, of the fixing rod is rotatably connected with a pawl clamped with the ratchet.

Through adopting above-mentioned technical scheme, when needing the suction pump at vertical direction downwardly movement, upwards rotate the pawl, pawl and ratchet separation, the ratchet no longer receives the restriction of pawl, and the serving pole can rotate, and then the suction pump moves at vertical direction.

When the water suction pump moves upwards in the vertical direction, the rope winding rod drives the ratchet wheel to rotate, the pawl cannot limit the rotation of the ratchet wheel in the rotation process of the ratchet wheel, the rope winding rod can rotate, and then the water suction pump moves in the vertical direction.

When the water suction pump does not need to move in the vertical direction, the pawl is connected with the ratchet wheel in a clamping mode, the ratchet wheel cannot rotate under the limiting effect of the pawl, the rope winding rod fixedly connected with the ratchet wheel is fixed, the rope winding rod cannot rotate, and therefore the water suction pump cannot move in the vertical direction.

Optionally, a T-shaped limiting groove is formed in the upper surface of the second supporting plate in a downward mode, a limiting block is connected in the limiting groove in a sliding mode, and a limiting rod used for lapping the pawl is fixedly connected to one side, close to the pawl, of the limiting block.

Through adopting above-mentioned technical scheme, when needing the downthehole ponding of discharge deep hole, stir the gag lever post upwards, the gag lever post drives the stopper and upwards slides along the spacing groove, rotates the pawl and to keeping away from ratchet one side motion, stirs the stopper downwards, pawl and gag lever post overlap joint, and the pawl loses the limiting displacement to the ratchet this moment, and ratchet rotation drives the rope winding rod and rotates, makes the lifting rope from the rope winding rod, and the suction pump falls along the deep hole, normally carries out drainage work until falling to the hole bottom. The overlapping of the pawl and the limiting rod reduces the possibility that the pawl falls back to one side close to the ratchet wheel and is clamped with the ratchet wheel to cause the rope winding rod to be incapable of rotating.

When the drainage work is finished, the rotating pawl moves to one side far away from the ratchet wheel, the limiting block is stirred upwards, the pawl is separated from the limiting rod, the rotating pawl moves to one side close to the ratchet wheel, the pawl is connected with the ratchet wheel in a clamping mode, when the water suction pump does not need to move in the vertical direction, the pawl limits the rotation of the ratchet wheel, and the possibility that the water suction pump moves in the vertical direction is reduced.

Optionally, a handle is fixedly connected to the upper surface of the water suction pump.

Through adopting above-mentioned technical scheme, the handle can make things convenient for operating personnel to transfer or carry and carry the action to the suction pump.

Optionally, the suction pump is fixedly connected with a filter screen along the circumferential direction of the water pumping port.

Through adopting above-mentioned technical scheme, the filter screen has effectively reduced in the deep hole the possibility that the water pipe is blockked up to lead to the unable normal drainage of suction pump to small stone, improves the efficiency of drainage work.

Optionally, the lower surface of the fixing plate is fixedly connected with a roller, and the upper surface of the fixing plate is fixedly connected with a handle.

By adopting the technical scheme, the operating personnel pushes the handle to enable the fixing plate to be simply and conveniently moved and transported by the roller, so that the operating personnel saves labor and time and improves the deep hole drainage efficiency.

In summary, the present application includes at least one of the following beneficial technical effects:

1. compared with a self-made small barrel, the water pump has larger water pumping amount in unit time, and the efficiency of draining accumulated water in a deep hole is improved;

2. the filter screen is fixedly connected with the circumference of the water suction pump, so that the possibility that small stones contained in accumulated water in the deep hole block the water suction pump to influence the normal water drainage of the water suction pump can be reduced;

3. when the water suction pump does not need to move along the vertical direction, the pawl is clamped with the ratchet wheel, the pawl limits the rotation of the ratchet wheel, the rope coiling rod is further fixed, and the possibility that the water suction pump moves along the vertical direction is reduced.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present application.

Fig. 2 is a schematic structural view of a lifting rope and a lifting lug embodied in the embodiment of the present application.

FIG. 3 is a schematic view of a ratchet and pawl embodying the present embodiment.

Fig. 4 is a schematic structural diagram showing a limiting groove and a limiting block in the embodiment of the present application.

Fig. 5 is a schematic structural view of a pawl and a limiting rod in the embodiment of the present application.

Fig. 6 is a schematic structural diagram of a filter screen embodied in the embodiment of the present application.

Description of reference numerals: 1. a fixing plate; 11. reserving a hole; 12. a first support plate; 13. a second support plate; 14. a third support plate; 2. a water pump; 21. lifting lugs; 22. a water outlet; 23. a handle; 24. a filter screen; 3. a pull-up assembly; 31. a rope winding rod; 32. lifting a rope; 33. a first lifting rod; 34. a second lifting rod; 4. a locking assembly; 41. a ratchet wheel; 42. fixing the rod; 43. a pawl; 44. a limiting groove; 45. a limiting block; 46. a limiting rod; 5. a roller; 6. a handle.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses deep hole ponding eduction gear.

Referring to fig. 1, a deep hole accumulated water discharging device comprises a fixing plate 1, wherein a preformed hole 11 is formed in the upper surface of the fixing plate 1 in a downward mode. A first support plate 12 and a second support plate 13 which are parallel to each other are fixedly connected to the upper surface of the fixing plate 1.

Referring to fig. 1 and 2, the accumulated water discharging device further includes a water suction pump 2, a lifting lug 21 is fixedly connected to the upper surface of the water suction pump 2, the water suction pump 2 is provided with a water outlet 22, and the water outlet 22 is fixedly connected with a hose (not shown in the figure) for discharging accumulated water. A lifting component 3 is connected between the first support plate 12 and the second support plate 13, and the lifting component 3 is connected with a lifting lug 21.

When accumulated water in the deep hole needs to be discharged, an operator firstly places the fixing plate 1 above the deep hole, and then places the water suction pump 2 in the deep hole through the preformed hole 11. Operating personnel makes suction pump 2 along deep hole downstream through lifting to draw subassembly 3, treats that suction pump 2 when arriving the deep hole bottom, and suction pump 2 begins to draw water, and ponding in the deep hole is discharged to the earth's surface through the hose under suction pump 2's effect.

When the drainage work is finished, an operator enables the water suction pump 2 to move upwards along the deep hole through the lifting assembly 3, and after the water suction pump 2 is lifted to leave the deep hole, the operator places the water suction pump 2 on the fixing plate 1.

Referring to fig. 1 and 2, lifting assembly 3 includes a rope winding rod 31 rotatably coupled to first support plate 12 and second support plate 13, one end of rope winding rod 31 passing through first support plate 12, and the other end of rope winding rod 31 passing through second support plate 13. The rope winding rod 31 is connected with a lifting rope 32, one end of the lifting rope 32 is fixedly connected with the rope winding rod 31, and the other end of the lifting rope 32 is fixedly connected with the lifting lug 21.

Referring to fig. 1, one end of the rope winding rod 31 penetrating through the first support plate 12 is fixedly connected with a first lifting rod 33, the first lifting rod 33 is perpendicular to the rope winding rod 31, one end of the first lifting rod 33 far away from the rope winding rod 31 is fixedly connected with a second lifting rod 34, and the second lifting rod 34 is perpendicular to the first lifting rod 33 and parallel to the rope winding rod 31.

When the water suction pump 2 needs to be placed in the deep hole, the second lifting rod 34 is rotated, the rope winding rod 31 is driven to rotate through the first lifting rod 33, the lifting rope 32 gradually leaves the rope winding rod 31 and falls, and the water suction pump 2 moves downwards along the deep hole. When the water suction pump 2 needs to be lifted out of the deep hole, the second lifting rod 34 rotates reversely, the rope winding rod 31 is driven to rotate reversely through the first lifting rod 33, the lifting rope 32 is wound on the rope winding rod 31, and the water suction pump 2 moves upwards along the deep hole.

Referring to fig. 1 and 2, a locking assembly 4 is disposed between the second support plate 13 and the rope winding rod 31, and when the suction pump 2 does not need to move in the vertical direction, the locking assembly 4 fixes the rope winding rod 31, and at this time, it is not necessary for a worker to hold the second lifting rod 34 to fix the rope winding rod 31. When the water suction pump 2 needs to move in the vertical direction, the locking assembly 4 releases the restriction on the rope winding rod 31, and the rope winding rod 31 can rotate.

Referring to fig. 1 and 3, the locking assembly 4 includes a ratchet 41 fixedly connected to one end of the rope winding rod 31 penetrating through the second support plate 13, a fixing rod 42 fixedly connected to the second support plate 13 is disposed above the ratchet 41, the fixing rod 42 is rotatably connected to a pawl 43, and one end of the pawl 43 away from the fixing rod 42 is engaged with the ratchet 41.

When the lifting rope 32 is wound on the rope winding rod 31, the rope winding rod 31 drives the ratchet wheel 41 to rotate, and the pawl 43 does not limit the rotation of the ratchet wheel 41 during the rotation of the ratchet wheel 41.

When the rope 32 is not required to be wound on the rope winding rod 31, the operator stops rotating the second lifting rod 34, and the pawl 43 is clamped with the ratchet wheel 41 to fix the rope winding rod 31.

When the lifting rope 32 needs to be lifted off the rope winding rod 31, the pawl 43 is rotated upwards, the pawl 43 is separated from the ratchet wheel 41, the ratchet wheel 41 is not limited by the pawl 43 any more, and the rope winding rod 31 can rotate.

Referring to fig. 3 and 4, the upper surface of the second support plate 13 is provided with a limiting groove 44 downward, the limiting groove 44 is a "T" shaped groove, the limiting groove 44 penetrates through one side of the second support plate 13 close to the ratchet 41, a limiting block 45 is slidably connected in the limiting groove 44, and the limiting block 45 is a "T" shaped block. A limiting rod 46 is fixedly connected to one side of the limiting block 45 close to the pawl 43.

Referring to fig. 3 and 5, when the pawl 43 needs to be separated from the ratchet wheel 41, the limiting rod 46 is firstly pulled upwards, the limiting rod 46 drives the limiting block 45 to slide upwards along the limiting groove 44, the pawl 43 is rotated to separate the pawl 43 from the ratchet wheel 41, the limiting rod 46 is pulled downwards, the limiting rod 46 drives the limiting block 45 to slide downwards along the limiting groove 44, the pawl 43 is rotated towards one side close to the ratchet wheel 41, the pawl 43 is lapped with the limiting block 45, the limiting rod 46 limits and fixes the pawl 43 at the moment, and the possibility that the pawl 43 rotates towards one side close to the ratchet wheel 41 is reduced.

When the pawl 43 needs to be clamped with the ratchet wheel 41, the pawl 43 is rotated to one side far away from the limiting rod 46, so that the pawl 43 is separated from the limiting rod 46, the limiting rod 46 is shifted upwards, the limiting rod 46 drives the limiting block 45 to slide upwards along the limiting groove 44, the pawl 43 is rotated to one side close to the ratchet wheel 41, the pawl 43 is clamped with the ratchet wheel 41, the limiting rod 46 is shifted downwards, and the limiting rod 46 drives the limiting block 45 to slide downwards along the limiting groove 44.

Referring to fig. 1 and 6, a filter screen 24 is fixedly connected to the circumference of the water pump 2, and the filter screen 24 can reduce the possibility that small stones contained in the accumulated water in the deep hole block the water pump 2, thereby reducing the possibility that the water pump 2 cannot pump water normally.

Referring to fig. 1, a third support plate 14 is fixedly connected between the first support plate 12 and the second support plate 13, and the third support plate 14 improves the stability of the integral connection of the first support plate 12 and the second support plate 13.

Referring to fig. 1, the fixed surface of the fixed plate 1 is fixedly provided with the roller 5, and the roller 5 can enable the fixed plate 1 to be moved to different deep holes on the surface of the mine ground more quickly to perform drainage work, so that the drainage efficiency is improved.

Referring to fig. 1, one side fixedly connected with handle 6 that fixed plate 1 upper surface is close to second backup pad 13, handle 6 can make the operating personnel more laborsaving convenient when transporting fixed plate 1.

Referring to fig. 2, a lifting handle 23 is fixedly connected to the upper surface of the water suction pump 2, and the lifting handle 23 is convenient for an operator to place the water suction pump 2 into the preformed hole 11 or lift the water suction pump 2 to the fixing plate 1.

The implementation principle of the embodiment of the application is as follows: when having ponding in the deep hole and needing to discharge, portable handle 23 of operating personnel moves suction pump 2 directly over the deep hole, stir gag lever post 46 upwards, gag lever post 46 drives stopper 45 and upwards slides along spacing groove 44, stir pawl 43 to keeping away from ratchet 41 one side, later stir gag lever post 46 downwards, gag lever post 46 drives stopper 45 and downwards slides along spacing groove 44, pawl 43 and gag lever post 46 overlap joint, rotate second lifting rod 34, make serving 31 to rotate through first lifting rod 33, lifting rope 32 leaves serving 31, suction pump 2 falls along the deep hole, until lifting rope 32 is crooked, show that suction pump 2 has sunk to the hole bottom. At this time, the second lifting rod 34 stops rotating, and the accumulated water in the hole is finally discharged to the ground surface through the hose under the action of the water suction pump 2.

When the drainage operation is completed, the pawl 43 is rotated in the direction away from the ratchet wheel 41, the pawl 43 is separated from the limiting rod 46, the limiting rod 46 is pulled upwards, the limiting rod 46 drives the limiting block 45 to slide upwards along the limiting groove 44, then the pawl 43 is rotated towards the side close to the ratchet wheel 41, the pawl 43 is clamped with the ratchet wheel 41, the second lifting rod 34 is rotated in the opposite direction, the second lifting rod 34 drives the first lifting rod 33 to rotate, the rope winding rod 31 rotates in the opposite direction, the lifting rope 32 is wound on the rope winding rod 31, the water pump 2 rises along the deep hole until the lifting handle 23 extends out of the ground surface, the rotation of the second lifting rod 34 is stopped, the pawl 43 limits the ratchet wheel 41 to rotate in the opposite direction, an operator tightly holds the lifting handle 23, pulls out the water pump 2 from the deep hole, and places the water pump 2 on the fixing plate 1.

The above are preferred embodiments of the present application, and the scope of protection of the present application is not limited thereto, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a deep hole ponding eduction gear which characterized in that: including fixed plate (1), preformed hole (11) have been seted up in fixed plate (1), fixed surface is connected with first backup pad (12) and second backup pad (13) on fixed plate (1), be connected with between first backup pad (12) and second backup pad (13) and carry and pull subassembly (3), it is connected with suction pump (2) to carry and pull subassembly (3), suction pump (2) are provided with delivery port (22), delivery port (22) fixedly connected with hose.

2. The deep hole ponding eduction gear of claim 1, characterized in that: carry and draw subassembly (3) including rotating ropewinder pole (31) of connecting between first backup pad (12) and second backup pad (13), ropewinder pole (31) fixedly connected with lifting rope (32), lifting rope (32) and suction pump (2) fixed connection, the first lifting rod (33) of one end fixedly connected with of ropewinder pole (31), the one end fixedly connected with second lifting rod (34) of ropewinder pole (31) are kept away from in first lifting rod (33).

3. A deep hole ponding drainage device according to claim 2, characterized in that: one end, far away from the first lifting rod (33), of the rope rolling rod (31) is connected with a locking assembly (4) used for fixing the rope rolling rod (31).

4. A deep hole ponding drainage device according to claim 3, characterized in that: locking Assembly (4) include with serving pole (31) fixed connection's ratchet (41), second backup pad (13) fixed connection has dead lever (42), the one end rotation that second backup pad (13) were kept away from in dead lever (42) is connected with pawl (43) with ratchet (41) joint.

5. A deep hole ponding drainage device according to claim 4, characterized in that: the upper surface of the second supporting plate (13) is downwards provided with a T-shaped limiting groove (44), a limiting block (45) is connected in the limiting groove (44) in a sliding mode, and one side, close to the pawl (43), of the limiting block (45) is fixedly connected with a limiting rod (46) used for overlapping the pawl (43).

6. A deep hole ponding drainage device according to claim 1, characterized in that: and a lifting handle (23) is fixedly connected to the upper surface of the water suction pump (2).

7. The deep hole ponding eduction gear of claim 1, characterized in that: the water suction pump (2) is circumferentially and fixedly connected with a filter screen (24).

8. The deep hole ponding eduction gear of claim 1, characterized in that: the fixed surface of fixed plate (1) is fixedly connected with gyro wheel (5), fixed surface is fixedly connected with handle (6) on fixed plate (1).

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