CN220059489U - Intelligent hydraulic deep water core drilling device - Google Patents

Abstract

The utility model provides an intelligent hydraulic deep water core drilling device, which comprises a triangular support frame, wherein two ends of a bottom rod in the triangular support frame are provided with hinged inclined support rods and guide frames, telescopic rods which are adjusted in a telescopic way are arranged on the inclined support rods, the end parts of the telescopic rods are propped against the guide frames to slide, the guide frames are also provided with sliding hydraulic driving machines, and the end parts of the hydraulic driving machines are fixedly provided with hydraulic rotary drills and annular blades; the hydraulic machine is characterized by further comprising a hydraulic machine, wherein a trolley in the hydraulic machine is fixedly provided with a three-cylinder water pump, and a pumping machine and a pressurizing machine are arranged in the three-cylinder water pump; the hydraulic driver and the hydraulic rotary drill are connected in parallel with the hydraulic press through the water outlet pipe and the water return pipe, and the hydraulic press drives the hydraulic driver to lean against the guide frame to move and feed, so that the hydraulic rotary drill is driven to drive the annular blade to rotate for cutting. The hydraulic pump is driven by the hydraulic pump, so that the underwater electric shock risk of personnel is reduced, the overall operation safety and the construction efficiency are greatly improved, and the hydraulic pump has good economic benefits.

Description

Intelligent hydraulic deep water core drilling device

Technical Field

The utility model relates to the technical field of drilling operation, in particular to an intelligent hydraulic deep water core drilling device.

Background

Drilling holes on the masonry structure under the deepwater condition, and perforating holes, drainage holes or pipelines for underwater hoisting of the masonry structure. The drilling machine is operated under water by a hand-held drilling machine for deep water area personnel, a diver is influenced by water pressure and rapid flow, the drilling construction difficulty of a masonry structure is greatly increased, the drilling efficiency is low, the underwater operation time of the diver is prolonged, and high potential safety hazards exist. The conventional motor is easy to cause personnel leakage and electric shock accidents in underwater drilling, the safety risk is extremely high, the intelligent hydraulic core drilling machine is only fixed on a masonry structure, and manual handheld equipment is replaced by hydraulic driving. The device has automation, intellectualization, simple operation, high working efficiency, safer construction, and solves the problems of high difficulty and high safety risk of underwater drilling construction.

Disclosure of Invention

The utility model mainly aims to provide an intelligent hydraulic deep water core drilling device which solves the problems in the background technology.

In order to solve the technical problems, the utility model adopts the following technical scheme: the device comprises a triangular support frame, wherein two ends of a bottom rod in the triangular support frame are provided with hinged inclined support rods and guide frames, telescopic rods for telescopic adjustment are arranged on the inclined support rods, the end parts of the telescopic rods are propped against the guide frames to slide, the guide frames are also provided with sliding hydraulic driving machines, and the end parts of the hydraulic driving machines are fixedly provided with hydraulic rotary drills and annular blades;

the hydraulic machine is characterized by further comprising a hydraulic machine, wherein a trolley in the hydraulic machine is fixedly provided with a three-cylinder water pump, and a pumping machine and a pressurizing machine are arranged in the three-cylinder water pump;

the hydraulic driver and the hydraulic rotary drill are connected in parallel with the hydraulic press through the water outlet pipe and the water return pipe, and the hydraulic press drives the hydraulic driver to lean against the guide frame to move and feed, so that the hydraulic rotary drill is driven to drive the annular blade to rotate for cutting.

Preferably, both sides of the guide frame are provided with sliding rails, the end parts of the telescopic rods are clamped on the sliding rails through sliding seats and fixed through second locking bolts, and the end parts of the telescopic rods are hinged in the sliding seats;

two sides of a driving machine sliding seat in the hydraulic driving machine are provided with a plurality of shaft wheels, and the shaft wheels are clamped on the sliding rail to move.

Preferably, a hydraulic device is fixedly arranged on the sliding seat of the driving machine and used for controlling the rotation of the driving shaft wheel so as to be propped against the sliding rail of the guide frame to move.

Preferably, the two sides of the end part of the diagonal brace are provided with idler wheels, and the idler wheels are propped against the masonry structure and used for moving in the process of lowering the triangular support frame;

the telescopic rod and the diagonal brace are respectively provided with a plurality of through holes, and the telescopic rod and the diagonal brace are fixedly connected through the first locking bolts penetrating through the through holes.

Preferably, the bottom of the diagonal brace and the guide frame are provided with a front fixing plate and a rear fixing plate which are hinged, and the front fixing plate and the rear fixing plate are connected through expansion bolts driven into the masonry structure, so that the triangular support frame is fixed.

Preferably, the guide frames are provided with a plurality of hollow holes, so that the overall weight and the water resistance are reduced.

Preferably, the three-cylinder water pump is provided with a gas release valve, one side of the three-cylinder water pump is provided with a circulating water outlet and a circulating water inlet, and the water outlet pipe and the water return pipe are respectively communicated with the circulating water outlet and the circulating water inlet;

the main pipelines of the water outlet pipe and the water return pipe are respectively provided with a directional valve and a water pressure gauge.

The intelligent hydraulic deep water core drilling device is simple to operate, the drilling device is only attached to a masonry structure manually, the hydraulic rotary drill is fed on the guide frame at a constant speed, holes can be cut smoothly in a circular mode, the hydraulic water pump is used for driving, underwater electric shock risks of personnel are reduced, overall operation safety and construction efficiency are greatly improved, and good economic benefits are achieved.

Drawings

The utility model is further illustrated by the following examples in conjunction with the accompanying drawings:

FIG. 1 is a schematic view of a drill assembly of the present utility model;

FIG. 2 is a schematic diagram of a drilling operation of the drilling apparatus of the present utility model;

FIG. 3 is a schematic illustration of the hydraulic machine connection of the present utility model;

FIG. 4 is a view showing the construction of the tripod of the present utility model;

FIG. 5 is a view of the hydraulic drive of the present utility model in connection with a hydraulic rotary drill;

FIG. 6 is a structural view of the hydraulic machine of the present utility model;

in the figure: a masonry structure 1; a crane 2; a hydraulic press 3; a carriage 301; a three-cylinder water pump 302; a release valve 303; a pumping machine 304; a pressurizing machine 305; a circulation water outlet 306; a circulation water inlet 307; a triangular support frame 4; a guide frame 401; a bottom bar 402; diagonal brace 403; a telescopic rod 404; a first locking bolt 405; a slide base 406; a roller 407; a front fixing plate 408; a rear fixing plate 409; a second locking bolt 410; a ring blade 5; a hydraulic drive machine 6; a drive machine slide 601; a wheel 602; a hydraulic press 603; a hydraulic rotary drill 7; a water outlet pipe 8; a return pipe 9; a water pressure gauge 10; a directional valve 11; expansion bolts 12.

Detailed Description

Example 1

As shown in fig. 1-6, an intelligent hydraulic deep water core drilling device comprises a triangular support frame 4, wherein two ends of a bottom rod 402 in the triangular support frame 4 are provided with hinged inclined support rods 403 and a guide frame 401, telescopic rods 404 which are in telescopic adjustment are arranged on the inclined support rods 403, the end parts of the telescopic rods 404 are propped against the guide frame 401 to slide, a sliding hydraulic driving machine 6 is further arranged on the guide frame 401, and the end parts of the hydraulic driving machine 6 are fixedly provided with a hydraulic rotary drill 7 and an annular blade 5;

the hydraulic machine 3 is further included, a three-cylinder water pump 302 is fixedly arranged on a trolley 301 in the hydraulic machine 3, and a pumping machine 304 and a pressurizing machine 305 are arranged in the three-cylinder water pump 302;

the hydraulic driver 6 and the hydraulic rotary drill 7 are connected in parallel with the water return pipe 9 on the hydraulic machine 3 through the water outlet pipe 8, the hydraulic driver 6 is driven by the hydraulic machine 3 to abut against the guide frame 401 to move and feed, and the hydraulic rotary drill 7 is driven to drive the annular blade 5 to rotationally cut. With the structure, the triangular support frame 4 is provided with the hydraulic driver 6 and the hydraulic rotary drill 7, the hydraulic driver 6 can drive the hydraulic rotary drill 7 to feed, and the hydraulic rotary drill 7 drives the annular blade 5 to cut, so that drilling and coring are performed; the triangular support frame 4 can also be used for angle adjustment, so that the drilling coring can be carried out by matching with the designed drilling angle; the hydraulic machine 3 provides power for the hydraulic driver 6 and the hydraulic rotary drill 7, so that personnel injury caused by underwater electric leakage is avoided.

Preferably, both sides of the guide frame 401 are provided with slide rails, the end part of the telescopic rod 404 is clamped on the slide rails through the sliding seat 406 and is fixed through the second locking bolt 410, and the end part of the telescopic rod 404 is hinged in the sliding seat 406;

a plurality of shaft wheels 602 are arranged on two sides of a driving machine sliding seat 601 in the hydraulic driving machine 6, and the shaft wheels 602 are clamped on sliding rails to move. With this structure, the sliding seat 406 is abutted against the sliding rail of the guide frame 401 to slide, so that the angle of the triangular support frame 4 is adjusted; the driver sliding seat 601 is moved by the rotation of the plurality of shaft wheels 602 to abut against the sliding rail of the guide frame 401, so that feeding during drilling is realized.

Preferably, a hydraulic device 603 is fixedly arranged on the sliding seat 601 of the driving machine, and the hydraulic device 603 is used for controlling the driving shaft wheel 602 to rotate so as to abut against the sliding rail of the guide frame 401 to move. With this structure, the hydraulic press 603 can drive the shaft wheel 602 to move on the slide rail of the guide frame 401, and the movement control is smoother and more accurate.

Preferably, the two sides of the end of the diagonal brace 403 are provided with rollers 407, the rollers 407 resting on the masonry structure 1 for movement during lowering of the tripod 4;

the telescopic rod 404 and the diagonal brace 403 are respectively provided with a plurality of through holes, and are fixedly connected through the through holes by a first locking bolt 405. In the structure, the triangular support frames 4 are hoisted and lowered by the crane 2, and the rollers 407 on two sides of the bottom of the triangular support frames roll against the masonry structure 1 in the lowering process, so that the lowering is smoother and more convenient; the telescopic rod 404 is supported in the inclined stay rod 403 to be telescopically adjusted, and is locked and fixed through a first locking bolt 405 passing through a through hole on the two after being adjusted in place.

Preferably, the diagonal braces 403 are provided with hinged front and rear anchor plates 408, 409 at the bottom of the guide frame 401, and the tripod 4 is secured by connecting the front and rear anchor plates 408, 409 by expansion bolts 12 driven into the masonry structure 1. With this configuration, the front fixing plate 408 and the rear fixing plate 409 are positioned in accordance with the installation positions of the rear dimension of the ring blade 5 mounted on the tripod 4, and the expansion bolts 12 are driven into the masonry structure 1 in advance, and after the tripod 4 is lowered in place, the expansion bolts 12 can be used to fix and install the tripod 4.

Preferably, the guide frames 401 are provided with a plurality of hollow holes, thereby reducing the overall weight and water resistance.

Preferably, the three-cylinder water pump 302 is provided with a gas release valve 303, one side of the three-cylinder water pump is provided with a circulating water outlet 306 and a circulating water inlet 307, and the water outlet pipe 8 and the water return pipe 9 are respectively communicated with the circulating water outlet 306 and the circulating water inlet 307;

the main pipelines of the water outlet pipe 8 and the water return pipe 9 are respectively provided with a directional valve 11 and a water pressure gauge 10. In this structure, the pressurizing machine 305 is used for pressurizing the water, the pressurized water is conveyed to the hydraulic rotary drill 7 and the hydraulic driver 6 through the pumping machine 304, so that the hydraulic rotary drill is driven, and the hydraulic pressure gauge 10 can display the pumping water pressure value and can be used as a control basis; the directional valve 11 is used to prevent the water from flowing back under pressure.

Example 2

As shown in fig. 1 to 6, further description is given in connection with example 1: the method comprises the following steps: the method comprises the following steps:

step one, correspondingly adjusting the triangular support frame 4 according to the drilling angle of the masonry structure 1, and screwing the first locking bolt 405 and the second locking bolt 410 so as to enable the triangular support frame 4 to form a stable triangle;

step two, according to the size of the triangular support frame 4 after being fixed, an expansion bolt 12 is driven into the masonry structure 1, so that the annular blade 5 can be opposite to the drilling position after the triangular support frame 4 is installed in place;

step three, connecting the hydraulic press 3 with the hydraulic driver 6 and the hydraulic rotary drill 7 through a water outlet pipe 8 and a water return pipe 9, and installing a water pressure gauge 10 and a directional valve 11 on a pipeline;

step four, before launching, performing test running on the shore, driving a hydraulic driver 6 and a hydraulic rotary drill 7 to operate through a hydraulic press 3, and checking whether the operation state meets the requirement;

step five, after the equipment is checked to be correct, the power is cut off to drain, the drilling device is lowered through the crane 2, the idler wheels 407 are abutted against the masonry structure 1 to roll, and the smoothness of the lowering process is ensured;

step six, after the drilling device is lowered to the drilling position, the expansion bolts 12 are connected with the front fixing plate 408 and the rear fixing plate 409 to complete the installation and fixation of the triangular support frame 4;

step seven, the annular blade 5 is aligned with the drilling position, a power supply is turned on, and the hydraulic press 3 is started to perform drilling operation;

and step eight, repeating the steps four to seven until drilling is completed.

Preferably, when the drilling depth is too long, the annular blade 5 can be independently dismounted under the power-off condition, the connecting shaft between the annular blade 5 and the hydraulic rotary drill 7 is lengthened after coring, the drilling operation is performed again, and the operation is repeated until the drilling depth reaches the requirement.

Preferably, when the number of the holes is too large, the drilling device is lifted to each hole site by the crane 2 to perform the drilling operation, and the operation is repeated until all the holes are drilled.

The above embodiments are only preferred embodiments of the present utility model, and should not be construed as limiting the present utility model, and the scope of the present utility model should be defined by the claims, including the equivalents of the technical features in the claims. I.e., equivalent replacement modifications within the scope of this utility model are also within the scope of the utility model.

Claims (7)

1. An intelligent hydraulic deep water core drilling device is characterized in that: the device comprises a triangular support frame (4), wherein two ends of a bottom rod (402) in the triangular support frame (4) are provided with hinged inclined support rods (403) and guide frames (401), telescopic rods (404) which are telescopically regulated are arranged on the inclined support rods (403), the end parts of the telescopic rods (404) are propped against the guide frames (401) to slide, a sliding hydraulic driving machine (6) is further arranged on the guide frames (401), and the end parts of the hydraulic driving machine (6) are fixedly provided with a hydraulic rotary drill (7) and an annular blade (5);

the hydraulic machine (3) is further included, a three-cylinder water pump (302) is fixedly arranged on a trolley (301) in the hydraulic machine (3), and a pumping machine (304) and a pressurizing machine (305) are arranged in the three-cylinder water pump (302);

the hydraulic driver (6) and the hydraulic rotary drill (7) are connected in parallel with the water return pipe (9) on the hydraulic press (3) through the water outlet pipe (8), the hydraulic driver (6) is driven by the hydraulic press (3) to abut against the guide frame (401) to move and feed, and the hydraulic rotary drill (7) is driven to drive the annular blade (5) to rotate for cutting.

2. The intelligent hydraulic deepwater core drilling device according to claim 1, wherein: both sides of the guide frame (401) are provided with sliding rails, the end part of the telescopic rod (404) is clamped on the sliding rails through a sliding seat (406) to move and is fixed through a second locking bolt (410), and the end part of the telescopic rod (404) is hinged in the sliding seat (406);

two sides of a driving machine sliding seat (601) in the hydraulic driving machine (6) are provided with a plurality of shaft wheels (602), and the shaft wheels (602) are clamped on the sliding rail to move.

3. The intelligent hydraulic deepwater core drilling device according to claim 2, characterized in that: the driver sliding seat (601) is fixedly provided with a hydraulic device (603), and the hydraulic device (603) is used for controlling the driving shaft wheel (602) to rotate so as to abut against the sliding rail of the guide frame (401) to move.

4. The intelligent hydraulic deepwater core drilling device according to claim 1, wherein: rollers (407) are arranged on two sides of the end part of the diagonal brace (403), and the rollers (407) are abutted against the masonry structure (1) and used for moving in the descending process of the triangular support frame (4);

the telescopic rod (404) and the diagonal brace (403) are respectively provided with a plurality of through holes, and the telescopic rod and the diagonal brace are fixedly connected through the through holes by a first locking bolt (405).

5. The intelligent hydraulic deepwater core drilling device according to claim 1, wherein: the bottom of the diagonal brace (403) and the bottom of the guide frame (401) are provided with a front fixing plate (408) and a rear fixing plate (409) which are hinged, and the front fixing plate (408) and the rear fixing plate (409) are connected through expansion bolts (12) driven into the masonry structure (1), so that the triangular support frame (4) is fixed.

6. The intelligent hydraulic deepwater core drilling device according to claim 1, wherein: the guide frames (401) are provided with a plurality of hollow holes, so that the whole weight and the water resistance are reduced.

7. The intelligent hydraulic deepwater core drilling device according to claim 1, wherein: the three-cylinder water pump (302) is provided with a gas release valve (303), one side of the three-cylinder water pump is provided with a circulating water outlet (306) and a circulating water inlet (307), and the water outlet pipe (8) and the water return pipe (9) are respectively communicated with the circulating water outlet (306) and the circulating water inlet (307);

the main pipelines of the water outlet pipe (8) and the water return pipe (9) are respectively provided with a directional valve (11) and a water pressure gauge (10).