CN211081836U - Pressure testing device before drilling and grouting in drilling engineering - Google Patents

Abstract

The utility model relates to a pressure test device before drilling and grouting in drilling engineering, which comprises a sealing cover, a device neck, a device sleeve and at least three alloy gaskets; the lower end of the sealing cover is provided with an external thread which is connected with an internal thread of the neck opening of the device; the neck of the device is fixed at the upper end of the device sleeve, and the diameter of the neck of the device is larger than that of the device sleeve; the alloy gasket is attached to the top of the drill rod and placed on the inner wall of the neck opening of the device, and the alloy gasket is used for clamping the top of the drill rod; the side of the device sleeve is used for welding straight-through joints with different diameters. The utility model discloses the structure is simple and easy, processing is convenient, solves the problem of the tripping operation underdrill that causes in the current engineering sectional grouting that creeps into, improves the efficiency of construction, reduces construction cost, reduces the input of manpower and materials, further ensures construction safety, and application method is various, easy operation, light operation can show improvement engineer's work efficiency.

Description

Pressure testing device before drilling and grouting in drilling engineering

Technical Field

The utility model relates to a drilling engineering slip casting technical field especially relates to a pressure testing device before drilling engineering drilling slip casting.

Background

Along with the development and utilization of underground resources, drilling engineering is applied to various fields, such as petroleum, shale gas, coal bed gas exploitation, mine disaster treatment and the like, and is a better happy life for people. When grouting the stratum, in order to better optimize the grouting effect, the sectional grouting process is one of the preferred methods, and the method comprises the steps of completely starting up drilling tools in the hole after drilling for a certain distance, connecting a grouting station at the hole opening for grouting, then drilling down for hole cleaning and drilling to the next grouting section, and continuously circulating the processes until the designed hole depth is reached.

The sectional grouting method has the following problems: actual construction shows that when stratum is grouted, some regional cracks develop and some regional cracks do not develop, so that grouting is not performed in the regions meeting the designed grouting pressure; but the area can not be judged whether to accord with grouting pressure, after the drilling tool is required to be completely started, the drilling tool is connected with a grouting station to carry out pressurized-water pressure test, and then whether grouting is required is judged according to the pressure; along with the continuous increase of the hole depth, the drilling tool is continuously lengthened, so that the time consumed by the drill tripping and the drill tripping in the process is gradually increased, and meanwhile, the physical strength of engineering personnel, the waste of materials and the abrasion of equipment are increased; and even increase the risk of drilling accidents.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to solve the above-mentioned weak point that exists among the prior art.

In order to achieve the purpose, the utility model provides a pressure testing device before drilling and grouting in drilling engineering, which comprises a sealing cover, a neck opening of the device, a sleeve of the device and at least three alloy gaskets; the lower end of the sealing cover is provided with an external thread which is connected with an internal thread of the neck opening of the device; the neck of the device is fixed at the upper end of the device sleeve, and the diameter of the neck of the device is larger than that of the device sleeve; the alloy gasket is attached to the top of the drill rod and placed on the inner wall of the neck opening of the device, and the alloy gasket is used for clamping the top of the drill rod; the side of the device sleeve is used for welding straight-through joints with different diameters.

In one possible embodiment, a bottom protective cover is also attached to the bottom end of the device sleeve.

In one possible embodiment, the thread on the inside of the bottom protective cover can be screwed on the thread on the lower end of the device sleeve, and the inside of the bottom protective cover is a plastic protective layer.

In one possible embodiment, the lower end of the sealing cover is engraved with a thread groove, and the thread groove is wrapped with a raw adhesive tape.

In one possible embodiment, the upper end of the sealing cap is at the weld nut.

In one possible embodiment, the device neck is welded to the device sleeve upper end.

In one possible embodiment, a pulling rope is provided on the alloy shim.

In one possible embodiment, the device neck inner diameter is greater than the drill pipe top diameter and the alloy shim thickness is greater than the difference between the drill pipe top diameter and the drill pipe diameter.

In one possible embodiment, the length of the device cannula ranges from 1 to 1.5 m.

In one possible embodiment, the middle position of the through joint is connected with a pressure gauge.

The utility model has the advantages as follows:

(1) the utility model discloses the structure is simple and easy, processing is convenient, solves the problem of the brill that causes in the current engineering section slip casting that creeps into and bores down, improves the efficiency of construction, reduces construction cost, reduces the input of manpower and materials, further ensures construction safety.

(2) The utility model discloses application method is various, easy operation, and enough light operations can show improvement engineering personnel work efficiency.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly described below, and it is obvious that the drawings in the description below are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural view of a pressure testing device before drilling and grouting in drilling engineering provided by an embodiment of the present invention;

fig. 2 is a schematic structural diagram of an alloy gasket according to an embodiment of the present invention;

fig. 3 is a schematic structural view of a sealing cover according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a bottom protection cover according to an embodiment of the present invention;

description of the reference numerals

1-sealing cover, 2-device neck, 3-alloy gasket, 4-pressure gauge, 5-straight joint, 6-device sleeve, 7-hole, 8-portable nut, 9-lifting rope, 10-bottom protective cover, 11-protective cover plastic protective layer and 12-drill rod.

Detailed Description

The terms "first," "second," and the like in the description and in the claims and in the drawings of the present invention are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. Furthermore, the terms "comprises" and "comprising," as well as any variations thereof, are intended to cover a non-exclusive inclusion, such as a list of steps or elements. A method, system, article, or apparatus is not necessarily limited to those steps or elements explicitly listed, but may include other steps or elements not explicitly listed or inherent to such process, system, article, or apparatus.

In order to make up for the technical deficiency, the utility model provides a pressure testing device before drilling grouting in drilling engineering and a use method thereof, when the existing drilling engineering sectionally grouts stratum fractures, a drilling tool can be taken to carry out water pressure testing, and whether grouting is needed or not is judged according to pressure; the problem of engineering waste caused by tripping and tripping is directly solved.

The technical solution of the present invention will be described in further detail with reference to the accompanying drawings and embodiments.

As shown in fig. 1-4, the embodiment of the present invention provides a pressure testing device before drilling and grouting in drilling engineering, which comprises a sealing cover 1, a device neck 2, a device sleeve 6, a bottom protective cover 10 and at least three alloy gaskets 3.

The lower end of the sealing cover 1 is provided with an external thread which is connected with an internal thread of the neck opening 2 of the device; the device neck 2 is fixed at the upper end of the device sleeve 6, and the diameter of the device neck 2 is larger than that of the device sleeve 6.

The alloy gasket 3 is attached to the top of the drill rod 12 and placed on the inner wall of the device neck 2, and the top of the drill rod 12 is located on the alloy gasket 3.

The side part of the device casing 6 is used for welding the through joints 5 with different diameters, when the grouting pipe diameter changes, the welded through joint 5 is removed, then the through joint 5 which accords with the current pipe diameter is welded, comprehensively speaking, the through joints with different diameters can be welded and removed, and the bottom protective cover 10 is screwed at the bottom end of the device casing 6.

In one example, a thread groove is carved on the lower end of the sealing cover 1, and the thread groove is wrapped with a raw adhesive tape, so that the sealing performance can be effectively ensured during actual construction.

In one example, the upper end of the seal cap 1 is at a weld nut 8 to facilitate installation and removal of the seal cap 1 from the device neck finish 2.

In one example, the device neck 2 is welded to the device sleeve 6 at the upper end thereof, and the application is not further limited as to the manner of attachment of the device neck 2 to the device sleeve 6.

In one example, the alloy pad 3 is attached to the top of the drill pipe 12 and provided with a lifting rope 9, so that the alloy pad 3 is convenient to mount and dismount.

In one example, the diameter of the device neck 2 is matched with the diameter of a drill rod, and can be divided into a plurality of grades, particularly according to the diameters of the drill rods, common drilling engineering drill rod diameters are divided into four grades of 50mm, 89mm, 114mm and 126mm, for this purpose, the diameter of the device neck 2 is divided into A, B, C, D grades, and the device necks 2 of different grades can be detached or welded at the upper end of the device sleeve 6. In the embodiment, a grade B device neck 2 (corresponding to a drill rod with the diameter of 89 mm) is selected for explanation.

As an embodiment of the present invention, the alloy gaskets 3 are 3, 4 or N pieces, which completely surround the drill rod, and preferably 3 pieces are selected, and the alloy gaskets are equally divided into four grades of a1, B1, C1 and D1 according to the graded matching of the neck 2 of the device and the diameter of the drill rod, and the alloy gasket 3 of the B1 grade is selected for explanation in this embodiment. And calculating the total weight of all drilling tools according to the compressive data of the alloy steel in the laboratory, wherein the compressive strength of the alloy material selected by the alloy gasket 3 is greater than the total weight of the drilling tools in the engineering, and the inclination angle of the upper part of the alloy gasket 3 is consistent with the inclination angle of the top of the drill rod.

In one example, the inner diameter of the device neck 2 is larger than the diameter of the top of the drill rod, and the thickness of the alloy gasket 3 is larger than the difference between the diameter of the top of the drill rod and the diameter of the drill rod, so as to prevent the top of the drill rod from directly falling into the device casing 6, and if the drill rod has no diameter-variable top, the drilling tool is clamped on the device by connecting the drill rod through joint. The existing drill rod is more in types, for example, a drill rod with the diameter of 89mm (the drill rod is shown in the figure, the diameter of two ends is large, the diameter of the rod part is small) is 114mm (the outer diameter is invariable), the utility model discloses a device is to let the drilling tool cassette be at the well head, if adopt the drill rod with the diameter of 114mm, the upper portion adds a joint with the outer diameter of more than 114m, the field is called a direct joint. The clamping of the drilling tool on the device can be realized.

In one example, the length of the device sleeve 6 ranges from 1 m to 1.5m, the upper end of the device sleeve is welded with the neck 2 of the device, the lower end of the device sleeve is connected with the bottom protective cover 10, and the side part of the device sleeve 6 is welded with the through joint 5 with different diameters, so that the device sleeve can be connected with grouting pipe heads with different specifications. And the middle part of the straight joint 5 welded on the side part of the device pipe is connected with a pressure gauge 4, so that the pressure of the orifice can be effectively read during actual work.

In one example, the inner threads of the bottom protective cover 10 can be screwed onto the threads of the lower end of the device sleeve 6; inside is plastic protection layer 11, and plastic protection layer 11 intensity is greater than the weight of alloy gasket, can reduce bottom visor weight, makes things convenient for visor dismantlement, installation, can guarantee again that pressure testing device is in the transportation, and the alloy gasket of putting in inside does not roll off and loses.

The use of the above-described device is further illustrated below with reference to three examples.

Example one

Step one, before drilling, a pressure testing device with the sealing cover 1 and the bottom protective cover 10 removed is connected with the hole opening 7.

And step two, after the drilling work is finished, attaching the B1-grade alloy gasket 3 to a drill rod with the diameter of 89mm, slowly sliding the drill rod to the inside of the neck opening 2 of the device, and then slowly seating the top of the whole drill rod and the whole drilling tool on the alloy gasket 3.

And step three, screwing the sealing cover 1 on the neck 2 of the pressure testing device and sealing, connecting the head of the grouting pipe on a straight joint 5 at the side part of the pressure testing device and sealing, installing a pressure gauge 4, checking whether each joint is stable, and starting a grouting pump to perform pressure pressing and pressure testing.

Example two

Step one, a hydraulic clamp or a hanging clamp of the drilling machine is used for clamping the position, 1.5-2m away from the top end, of the last drill rod.

And step two, disassembling the power head of the drilling machine, and sleeving the pressure testing device with the sealing cover 1 and the bottom protective cover 10 removed on the exposed drill rod.

And step three, screwing the power head of the drilling machine on the drill rod, hoisting the drilling tool completely, and slowly sliding the pressure testing device down to the hole opening 7 and connecting and fixing the pressure testing device.

And step four, attaching the B1-grade alloy gasket 3 on a drill rod with the diameter of 89mm, slowly sliding the drill rod down to the inside of the neck opening 2 of the device, and then slowly seating the top of the whole drill rod and the whole drilling tool on the alloy gasket 3.

And fifthly, screwing the sealing cover 1 on the neck 2 of the pressure testing device and sealing, connecting the head of the grouting pipe on a straight joint 5 at the side part of the pressure testing device and sealing, installing a pressure gauge 4, checking whether each joint is stable, and starting a grouting pump to perform pressure pressing and pressure testing.

EXAMPLE III

Step one, after drilling, the last drill rod of the drilling tool is taken out, and the rest drilling tools are clamped on an operation table.

And step two, sleeving the pressure test device with the sealing cover 1 removed and the bottom protective cover 10 from the bottom end of the last drill rod, connecting the drill rods to the drilling tool, and completely hoisting the drilling tool at the moment.

And step three, slowly sliding the pressure testing device down to the orifice 7 and connecting and fixing the pressure testing device.

And step four, attaching the B1-grade alloy gasket 3 on a drill rod with the diameter of 89mm, slowly sliding the drill rod down to the inside of the neck opening 2 of the device, and then slowly seating the top of the whole drill rod and the whole drilling tool on the alloy gasket 3.

And fifthly, screwing the sealing cover 1 on the neck 2 of the pressure testing device and sealing, connecting the head of the grouting pipe on a straight joint 5 at the side part of the pressure testing device and sealing, installing a pressure gauge 4, checking whether each joint is stable, and starting a grouting pump to perform pressure pressing and pressure testing.

The above-mentioned embodiments further explain the objects, technical solutions and advantages of the present invention in detail, it should be understood that the above-mentioned embodiments are only specific embodiments of the present invention, and are not intended to limit the protection scope of the present invention, and any modifications, improvements, etc. made on the basis of the technical solutions of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A pressure test device before drilling and grouting in drilling engineering is characterized by comprising a sealing cover (1), a device neck (2), a device sleeve (6) and at least three alloy gaskets (3);

the lower end of the sealing cover (1) is provided with an external thread which is connected with an internal thread of the neck opening (2) of the device; the device neck (2) is fixed at the upper end of the device sleeve (6), and the diameter of the device neck (2) is larger than that of the device sleeve (6);

the alloy gasket (3) is attached to the top of the drill rod and placed on the inner wall of the device neck (2), and the alloy gasket (3) is used for clamping the top of the drill rod;

the side of the device sleeve (6) is used for welding straight-through joints (5) with different diameters.

2. The device for testing the pressure in the drilling engineering before grouting according to claim 1, characterized in that a bottom protective cover (10) is further connected to the bottom end of the device casing (6).

3. The device for testing the pressure in the drilling engineering before grouting according to claim 2, characterized in that the threads on the inner side of the bottom protective cover (10) can be screwed on the threads at the lower end of the device casing (6), and the inside of the bottom protective cover (10) is provided with a plastic protective layer (11).

4. The device for testing the pressure before grouting in the drilling engineering according to claim 1, wherein a thread groove is carved at the lower end of the sealing cover (1), and the thread groove is wrapped with a raw adhesive tape.

5. The device for testing pressure before grouting in a drilling engineering borehole according to claim 1, characterized in that the upper end of the sealing cover (1) is at a welding nut (8).

6. The pressure testing device before drilling and grouting of the drilling engineering according to claim 1, characterized in that the device neck (2) is welded at the upper end of the device casing (6).

7. The device for testing the pressure before grouting in the drilling engineering according to claim 1, characterized in that a pulling-up rope (9) is arranged on the alloy gasket (3).

8. The device for testing pressure before grouting in a drilling engineering borehole is characterized in that the inner diameter of a neck (2) of the device is larger than the diameter of the top of a drill rod, and the thickness of an alloy gasket (3) is larger than the difference value between the diameter of the top of the drill rod and the diameter of the drill rod.

9. The device for testing pressure before grouting in a borehole of a drilling project according to claim 1, characterized in that the length of the device casing (6) is in the range of 1-1.5 m.

10. The pressure testing device before drilling and grouting in drilling engineering according to claim 1, characterized in that the middle position of the through joint (5) is connected with a pressure gauge (4).

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