KR102407811B1 - Ram cylinder installing apparatus for pipe ram unit of continuous circulation system - Google Patents

Abstract

The present invention is a ram cylinder installation for a pipe ram unit of a continuous water circulation system so that the assembly and installation of parts for positioning after a rod is fastened when assembling a ram cylinder of a pipe ram unit of a continuous water circulation system can be efficiently performed An apparatus, comprising: a pipe ram block formed in a polygonal column shape and provided as many as the number of sides of the polygonal column so as to be partially or entirely accommodated in a pipe ram chamber body through which a drill pipe passes vertically; a rod coupled along an installation groove recessed in the rear side of the pipe ram block and configured to move the pipe ram block closer or spaced apart toward an outer circumferential surface of the drill pipe passing through the pipe ram chamber body; a positioning unit inserted from both ends of the installation groove, and fixing the hooking piece of the rod end inserted along the installation groove to be disposed in the center of the installation groove; and an installation unit that is detachably coupled to the positioning unit and slides and inserts the positioning unit by a predetermined distance from both ends of the installation groove so that the positioning unit comes into contact with the left and right sides of the locking piece do it with

Description

Ram cylinder installation device for pipe ram unit of continuous water circulation system

The present invention relates to an apparatus for installing a ram cylinder for a pipe ram unit of a continuous water circulation system, and more particularly, to efficiently assemble and install parts for positioning after a rod is fastened when assembling a ram cylinder of a pipe ram unit. It relates to a ram cylinder installation device for a pipe ram unit of a continuous water circulation system.

When excavating rocks or sand to investigate the structure and condition of the stratum, or to explore underground resources on the seabed or land, it is necessary to keep the pressure of the mud in the drill part constant.

If the pressure of the mud is too low, the borehole wall is compressed and collapsed by the pore pressure of underground fluids and gases. Loss will occur in the process.

Therefore, it is important to maintain the pressure of the drilling mud within a limited pressure window, and for this purpose, a Continuous Circulation System (CCS) is used.

The continuous water circulation system induces continuous operation of the mud pump throughout the drilling process, including connection and disconnection of the drill pipe, so that the mud is continuously circulated within the drilling rig.

As a technology related to the continuous dilution circulation system, there may be mentioned such as "Ram unit test bed for continuous dilution circulation system" of Registered Patent No. 10-2260474, which was previously applied and registered by the present applicant.

Here, the pipe ram unit 200 is provided in the hexahedral pipe ram chamber 220 and the pipe ram block 240 and the pipe ram block 240 selectively mounted inside the pipe ram chamber 220 as shown in FIG. 8 . It is configured to include a pipe ram packer 260 to form an airtight performance.

At this time, the pipe ram block 240 is coupled to the cylinder so that the pipe ram packer 260 connected to the pipe ram block 240 reciprocates in the pipe ram chamber 220 so that it can contact or separate the drill pipe.

If the position of the distal end of the cylinder connected to the pipe ram block 240 is not accurately determined, the operation to smoothly contact or separate the drill pipe cannot be made, and the distance between the distal end of the cylinder and the pipe ram block 240 after a long period of time has elapsed. Brittleness occurred near the connection part, which could act as one of the factors shortening the lifespan of the entire device.

Therefore, there is an urgent need to develop a device for easily installing parts and the like that allow the distal end of the cylinder to maintain a state disposed in the center of the rear side of the pipe ram block 240 .

Registered Patent No. 10-2260474

The present invention was invented to improve the above problems, and when assembling the ram cylinder of the pipe ram unit, after the rod is fastened, the pipe of the continuous water circulation system can be efficiently assembled and installed for positioning. To provide a ram cylinder installation device for a ram unit.

In order to achieve the above object, the present invention is a pipe ram formed in the shape of a polygonal pillar and provided as many as the number of sides of the polygonal pillar so that some or all of it can be accommodated inside the pipe ram chamber body through which the drill pipe passes up and down. block; a rod coupled along an installation groove recessed in the rear side of the pipe ram block and configured to move the pipe ram block closer or spaced apart toward an outer circumferential surface of the drill pipe passing through the pipe ram chamber body; a positioning unit inserted from both ends of the installation groove, and fixing the hooking piece of the rod end inserted along the installation groove to be disposed in the center of the installation groove; and an installation unit detachably coupled to the positioning unit and slidingly inserting the positioning unit by a predetermined distance from both ends of the installation groove so that the positioning unit is in contact with the left and right sides of the engaging piece It is possible to provide a ram cylinder installation device for a pipe ram unit of a continuous water circulation system.

Here, the pipe ram block is connected to the bottom surface of the installation groove along the upper side of the upper and lower both sides of the installation groove which is recessed in the rear side of the pipe ram block to communicate with the left and right side ends of the pipe ram block. An upper rail groove which is recessed upward from the bottom surface and has a bottom surface formed on the same plane as the bottom surface of the installation groove, and a connection part that comes into contact with the bottom surface of the installation groove along a lower side of the upper and lower both sides of the installation groove It further includes a lower rail groove recessed downward and having a bottom surface formed on the same plane as the bottom surface of the installation groove, wherein the positioning unit slides through both ends of the upper rail groove and the lower rail groove coupled, the length of the imaginary line passing through the bottom surface of the installation groove and perpendicular to the center of each of the upper rail groove and the lower rail groove at the same time is greater than or equal to the diameter or width of the distal end of the rod, and is formed extending from the rod A coupling neck portion having a diameter or width corresponding to the width of the installation groove and disposed concentrically with an imaginary line passing through the axial direction of the rod is disposed in the center of the installation groove, the engaging piece extending from the end of the coupling neck portion An outer circumferential surface or an outer surface engages the upper rail groove and the lower rail groove.

In this case, the positioning unit includes a first crystal piece that is slidably inserted from one end of both ends of the upper rail groove and the lower rail groove respectively formed on both sides of the installation groove along the insertion direction of the positioning unit, and the installation groove and a second crystal piece slidably inserted from the other end of both ends of the upper rail groove and the lower rail groove, wherein the locking piece is disposed between the distal ends of each of the first crystal piece and the second crystal piece, The installation unit clamps the upper and lower surfaces of the first crystal piece to slide the first crystal piece along the upper rail groove and the lower rail groove, and clamps the upper and lower surfaces of the second crystal piece to make the second crystal piece 2 The crystal piece is characterized in that it slides along the upper rail groove and the lower rail groove.

In addition, the positioning unit includes a first upper engaging piece that protrudes in and out of an upper surface of the first crystal piece facing the upper rail groove, and the first upper engaging piece recessed upwardly in the upper rail groove. A first upper engaging groove for accommodating a, a first lower engaging piece protruding in and out from a lower surface of the first crystal piece facing the lower rail groove, and the first lower engaging piece recessed downwardly in the lower rail groove A first lower locking groove for accommodating the locking piece, a second upper locking piece protruding in and out from the upper surface of the second crystal piece facing the upper rail groove, and the upper rail groove are recessed upwards to form the second 2 A second upper locking groove for accommodating the upper locking piece, a second lower locking piece protruding in and out from a lower surface of the second crystal piece facing the lower rail groove, and a depression formed in the lower rail groove Further comprising a second lower engaging groove for accommodating the second lower engaging piece, the installation unit, the first upper engaging piece and the end surfaces of each of the first lower engaging piece, the upper surface and the lower surface of the first crystal piece The first crystal piece is slidably inserted along the upper rail groove and the lower rail groove by clamping it to be positioned on the same plane as the The second crystal piece is slidably inserted along the upper rail groove and the lower rail groove by clamping the second crystal piece to be positioned on the same plane as the upper and lower surfaces of the crystal piece.

In addition, the installation unit includes a first upper contact bar for clamping an upper surface of a first crystal piece inserted from one end among both ends of the installation groove among the positioning units, and a first lower contact bar for clamping a lower surface of the first crystal piece. a bar and a first clamping bracket having a first core body connecting the first upper contact bar and the first lower contact bar to each other, and the first clamping bracket is slidably reciprocable through the first core body and is in contact with the rear of the first crystal piece a first push block for sliding and inserting the first crystal piece along the upper rail groove and the lower rail groove formed on both sides of the installation groove; A third having a second upper contact bar clamping the upper surface of the crystal piece, a second lower contact bar clamping the lower surface of the second crystal piece, and a second core body connecting the second upper contact bar and the second lower contact bar to each other 2 Clamping brackets, sliding and reciprocating through the second core body, and contacting from the rear of the second crystal piece, sliding and inserting the second crystal piece along the upper rail groove and the lower rail groove formed on both sides of the installation groove It is characterized in that it includes a second push block.

According to the present invention having the above configuration, the assembly and installation of parts for positioning after the rod is fastened when assembling the ram cylinder of the pipe ram unit will be able to be efficiently performed.

1 is a cross-sectional conceptual view showing the overall coupling relationship of a ram cylinder installation device for a pipe ram unit of a continuous water circulation system according to an embodiment of the present invention;
2 is an exploded perspective view illustrating a relationship in which a positioning unit, which is a main part of a ram cylinder installation device for a pipe ram unit of a continuous water circulation system according to an embodiment of the present invention, is coupled to a pipe ram block together with a rod;
3 is a cross-sectional conceptual view showing a state in which a positioning unit, which is a main part of a ram cylinder installation device for a pipe ram unit of a continuous water circulation system according to an embodiment of the present invention, is coupled to a pipe ram block together with a rod;
4 is a cross-sectional conceptual view showing the internal structure of a positioning unit, which is a main part of a ram cylinder installation device for a pipe ram unit of a continuous water circulation system according to an embodiment of the present invention;
5 is a cross-sectional conceptual view showing the internal structure of an installation unit, which is a main part of a ram cylinder installation device for a pipe ram unit of a continuous water circulation system according to an embodiment of the present invention;
6 and 7 are cross-sectional conceptual views sequentially illustrating a process of coupling a positioning unit to a pipe ram block using a ram cylinder installation device for a pipe ram unit of a continuous water circulation system according to an embodiment of the present invention;
8 is an exploded perspective view showing the overall coupling relationship of the pipe ram unit of the conventional continuous water circulation system;

Advantages and features of the present invention, and methods for achieving them, will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below, but will be implemented in various different forms.

In the present specification, the present embodiment is provided to complete the disclosure of the present invention, and to fully inform those of ordinary skill in the art to which the present invention pertains to the scope of the invention.

And the invention is only defined by the scope of the claims.

Accordingly, in some embodiments, well-known components, well-known operations, and well-known techniques have not been specifically described to avoid obscuring the present invention.

In addition, like reference numerals refer to like elements throughout the specification, and terms used (referred to) in this specification are for the purpose of describing the embodiments and are not intended to limit the present invention.

In this specification, the singular also includes the plural unless specifically stated otherwise in the phrase, and elements and operations referred to as 'comprising (or having)' do not exclude the presence or addition of one or more other elements and operations. .

Unless otherwise defined, all terms (including technical and scientific terms) used herein may be used with the meaning commonly understood by those of ordinary skill in the art to which the present invention belongs.

In addition, terms defined in a commonly used dictionary are not ideally or excessively interpreted unless they are defined.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

First, FIG. 1 is a cross-sectional conceptual view showing the overall coupling relationship of a ram cylinder installation device for a pipe ram unit of a continuous water circulation system according to an embodiment of the present invention.

And, Figure 2 shows the positioning unit 300, which is a main part of the ram cylinder installation device for the pipe ram unit of the continuous water circulation system according to an embodiment of the present invention, is installed on the pipe ram block 120 together with the rod 210. It is an exploded perspective conceptual diagram showing the relationship to be combined.

And, Figure 3 shows the positioning unit 300, which is a main part of the ram cylinder installation device for the pipe ram unit of the continuous water circulation system according to an embodiment of the present invention, is installed on the pipe ram block 120 together with the rod 210. It is a cross-sectional conceptual diagram showing the combined state.

And, Figure 4 is a cross-sectional conceptual view showing the internal structure of the positioning unit 300, which is a main part of the ram cylinder installation device for the pipe ram unit of the continuous water circulation system according to an embodiment of the present invention.

5 is a cross-sectional conceptual view showing the internal structure of the installation unit 500, which is a main part of the ram cylinder installation device for the pipe ram unit of the continuous water circulation system according to an embodiment of the present invention.

In addition, FIGS. 6 and 7 show the process of coupling the positioning unit 300 to the pipe ram block 120 using a ram cylinder installation device for a pipe ram unit of a continuous water circulation system according to an embodiment of the present invention. It is a cross-sectional conceptual diagram sequentially showing.

For reference, the transparent arrow shown in the right direction in FIG. 1(a) indicates the movement direction of the first crystal piece 310, and the transparent arrow shown in the left direction in FIG. 1(b) is the second crystal piece 320. indicate the direction of movement of

In the present invention, as shown in FIGS. 1 and 2, the positioning unit 300 is disposed at the center of the rear side of the pipe ram block 120 at the distal end of the rod 210, but the above-described positioning unit 300 The embodiment may be applied to be installed in the pipe ram block 120 by the installation unit (500).

First, the pipe ram block 120 is formed in a polygonal column shape so that a part or all of the pipe ram chamber body 110 through which a drill pipe (hereinafter not shown) penetrates vertically can be accommodated by the number of sides of the polygonal column. it will be provided

Then, the rod 210 is coupled along the installation groove 121 recessed in the rear side of the pipe ram block 120 , and the pipe ram block 120 passes through the pipe ram chamber body 110 of the drill pipe. It is to close or spaced apart toward the outer circumferential surface.

In addition, the positioning unit 300 is inserted from both ends of the installation groove 121, and the engaging piece 212 of the distal end of the rod 210 inserted along the installation groove 121 is at the exact center of the installation groove 121. to be fixed in place.

In addition, the installation unit 500 is detachably coupled to the positioning unit 300 , and the positioning unit 300 is inserted by sliding the positioning unit 300 from both ends of the installation groove 121 by a predetermined distance, respectively, so that the positioning unit 300 is a locking piece. (212) is to be in contact with both sides of the left and right.

It goes without saying that the present invention can be applied to the above-described embodiments, and can also be applied to the following various embodiments.

First, as shown in FIG. 2 , the pipe ram block 120 is the upper part of the upper and lower both sides of the installation groove 121 which is recessed in the rear side of the pipe ram block 120 to communicate with the left and right side ends of the pipe ram block 120 . An upper rail groove 122 having a bottom surface formed on the same plane as the bottom surface of the installation groove 121 by being recessed upward from the connection part in contact with the bottom surface of the installation groove 121 along the side. can

In addition, the pipe ram block 120 is recessed downward from the connection part in contact with the bottom surface of the installation groove 121 along the lower side of the upper and lower both sides of the installation groove 121, and is the same as the bottom surface of the installation groove 121. A lower rail groove 123 having a bottom surface formed on a plane may be further provided.

Here, the positioning unit 300 will be slidably coupled through both ends of the upper rail groove 122 and the lower rail groove 123 .

At this time, the length of the imaginary line passing through the bottom surface of the installation groove 121 and perpendicular to the center of each of the upper rail groove 122 and the lower rail groove 123 at the same time is greater than or equal to the diameter or width of the distal end of the rod 210 . it is preferable

That is, the distal end of the rod 210 , specifically, the diameter or width of the engaging piece 212 to be described later is perpendicular to the center of each of the above-described upper rail groove 122 and lower rail groove 123 at the same time as the installation groove 121 . ) is less than or equal to the length of the imaginary line passing through the bottom surface, because the engaging piece 212 can be helpful in accurate positioning by the positioning unit 300 to be described later by sliding insertion.

In addition, the coupling neck portion 211 extending from the rod 210 and having a diameter or width corresponding to the width of the installation groove 121 and disposed concentric with an imaginary line passing through the axial direction of the rod 210 is installed. It can be seen that the groove 121 is disposed in the center.

In addition, it can also be grasped that the outer peripheral surface or the outer surface of the engaging piece 212 extending from the end of the coupling neck portion 211 engages the upper rail groove 122 and the lower rail groove 123 .

Here, it is also possible to grasp that the coupling neck portion 211 and the engaging piece 212 are slidably coupled along the installation groove 121 in which the upper rail groove 122 and the lower rail groove 123 are formed.

Meanwhile, the positioning unit 300 may include the first and second crystal pieces 310 and 320 as shown in FIGS. 3 and 4 .

The first crystal piece 310 is inserted by sliding from one end of both ends of the upper rail groove 122 and the lower rail groove 123 respectively formed on both sides of the installation groove 121 along the insertion direction of the positioning unit 300 . will become

The second crystal piece 320 is slidingly inserted from the other end of both ends of the installation groove 121 , the upper rail groove 122 , and the lower rail groove 123 .

Accordingly, the locking piece 212 is disposed between the distal end of each of the first crystal piece 310 and the second crystal piece 320 and at the same time at the center of the installation groove 121 and the upper and lower rail grooves 122 and 123 . will be placed

The distal end surface of the first crystal piece 310 is cut to correspond to the outer circumferential shape of the locking piece 212 to form an arc-shaped first contact cutout 310a in contact with the outer circumferential surface of one side of the locking piece 212. can

The distal end surface of the second crystal piece 320 is cut to correspond to the outer circumferential shape of the locking piece 212 to form a second contact cutout 320a of an arc shape in contact with the other outer circumferential surface of the locking piece 212. it might be

On the other hand, the positioning unit 300, looking more specifically, may apply the embodiment of the structure as follows.

That is, when the positioning unit 300 is viewed from the upper side of FIGS. 3 ( a ) and 4 ( a ), the upper rail groove 122 and the first crystal piece 310 facing the upper surface of the first crystal piece 310 protrude in and out. It may further include a first upper engaging piece (311a).

In addition, the positioning unit 300 may further include a first upper access hole 312a formed on the upper surface of the first crystal piece 310 .

In addition, the positioning unit 300 is embedded in the first crystal piece 310 to support the first upper locking piece 311a, and the first upper locking piece 311a is the upper surface of the first crystal piece 310 . It may further include a first upper support spring (313a) for generating an elastic force in a direction protruding from the.

In addition, the positioning unit 300 communicates with the first upper access hole 312a and is formed inside the upper portion of the first crystal piece 310 to include a first upper engaging piece 311a and a first upper support spring 313a. ) may further include a first upper working space (314a) for accommodating.

In addition, the positioning unit 300 may further include a first upper locking groove 315a which is recessed upwardly in the upper rail groove 122 to accommodate the first upper locking piece 311a.

In addition, the positioning unit 300 extends along the outer peripheral surface of the lower end of the first upper engaging piece 311a and is located on the ceiling surface of the first upper working space 314a having a larger diameter than the first upper access hole 312a. It may further include a first upper engaging flange (311pa) to be engaged.

In addition, the positioning unit 300 is formed to protrude downward from the bottom surface of the first upper engaging flange 311pa and has an outer peripheral surface facing the inner peripheral surface of the first upper support spring 313a. A first upper spring support rod 311da. may be further provided.

In addition, the positioning unit 300 is a first upper rod receiving groove ( 314ga) may be further provided.

In addition, the positioning unit 300 is recessed in a ring shape on the bottom surface of the first upper working space 314a and is disposed concentrically with the first upper rod receiving groove 314ga and the first upper supporting spring 313a. ) may further include a first upper spring seat groove 314sa for supporting the lower end.

On the other hand, the positioning unit 300, looking at the lower side of Figures 3 (a) and 4 (a), the lower rail groove 123 and facing the first crystal piece 310 that protrudes from the lower surface to be able to enter and exit It may further include a first lower engaging piece (311b).

In addition, the positioning unit 300 may further include a first lower access hole 312b formed on a lower surface of the first crystal piece 310 .

In addition, the positioning unit 300 is embedded in the first crystal piece 310 to support the first lower engaging piece 311b, and the first lower engaging piece 311b is the lower surface of the first crystal piece 310 . It may further include a first lower support spring (313b) for generating an elastic force in a direction protruding from the.

In addition, the positioning unit 300 communicates with the first lower access hole 312b and is formed inside the lower portion of the first crystal piece 310 to include a first lower engaging piece 311b and a first lower support spring 313b. ) may further include a first lower working space (314b) for accommodating.

In addition, the positioning unit 300 may further include a first lower engaging groove 315b which is recessed downwardly in the lower rail groove 123 to accommodate the first lower engaging piece 311b.

In addition, the positioning unit 300 extends along the outer circumferential surface of the upper end of the first lower engaging piece 311b and on the bottom surface of the first lower working space 314b having a larger diameter than the first lower access hole 312b. It may further include a first lower engaging flange (311pb) to be caught.

And, the positioning unit 300 is formed to protrude upward from the upper surface of the first lower engaging flange 311pb and has an outer peripheral surface facing the inner peripheral surface of the first lower support spring 313b. A first lower spring support rod 311db) may be further provided.

In addition, the positioning unit 300 is a first lower rod receiving groove ( 314gb) may be further provided.

In addition, the positioning unit 300 is recessed in a ring shape on the ceiling surface of the first lower working space 314b and is disposed concentrically with the first lower rod receiving groove 314gb and the first lower supporting spring 313b ) may further include a first lower spring seat groove (314sb) for supporting the upper end.

On the other hand, the positioning unit 300, looking at the upper side of Figs. 3 (b) and 4 (b), the upper rail groove 122 and facing the second crystal piece 320 from the upper surface of the upper surface to be protruded in and out It may further include a second upper engaging piece (321a).

In addition, the positioning unit 300 may further include a second upper access hole 322a formed on the upper surface of the second crystal piece 320 .

In addition, the positioning unit 300 is embedded in the second crystal piece 320 to support the second upper locking piece 321a, and the second upper locking piece 321a is the upper surface of the second crystal piece 320 . It may further include a second upper support spring (323a) for generating an elastic force in the protruding direction from the.

In addition, the positioning unit 300 communicates with the second upper access hole 322a and is formed inside the upper portion of the second crystal piece 320 to include a second upper engaging piece 321a and a second upper support spring 323a. ) may further include a second upper working space (324a) for accommodating.

In addition, the positioning unit 300 may further include a second upper engaging groove 325a which is recessed upwardly in the upper rail groove 122 to accommodate the second upper engaging piece 321a.

In addition, the positioning unit 300 extends along the outer peripheral surface of the lower end of the second upper engaging piece 321a and is on the ceiling surface of the second upper working space 324a having a larger diameter than the second upper access hole 322a. It may further include a second upper engaging flange 321pa to be caught.

And, the positioning unit 300 is formed to protrude from the bottom surface of the second upper engaging flange 321pa to the lower side and has an outer peripheral surface facing the inner peripheral surface of the second upper support spring 323a. A second upper spring support rod 321da. may be further provided.

In addition, the positioning unit 300 is a second upper rod receiving groove ( 324ga) may be further provided.

In addition, the positioning unit 300 is recessed in a ring shape on the bottom surface of the second upper working space 324a and is disposed concentrically with the second upper rod receiving groove 324ga and the second upper supporting spring 323a. ) may further include a second upper spring seat groove (324sa) for supporting the lower end.

On the other hand, the positioning unit 300, looking at the lower side of Figures 3 (b) and 4 (b), the lower rail groove 123 and facing the second crystal piece 320 protrudes from the lower surface to be able to enter and exit. A second lower engaging piece 321b may be further provided.

In addition, the positioning unit 300 may further include a second lower access hole 322b formed on a lower surface of the second crystal piece 320 .

And, the positioning unit 300 is built into the second crystal piece 320 to support the second lower locking piece 321b, and the second lower locking piece 321b is the lower surface of the second crystal piece 320 . It may further include a second lower support spring 323b for generating an elastic force in a direction protruding from the.

In addition, the positioning unit 300 communicates with the second lower access hole 322b and is formed in the lower inner side of the second crystal piece 320 to include a second lower engaging piece 321b and a second lower supporting spring 323b. ) may further include a second lower working space (324b) for accommodating.

In addition, the positioning unit 300 may further include a second lower locking groove 325b which is recessed downwardly in the lower rail groove 123 to accommodate the second lower locking piece 321b.

In addition, the positioning unit 300 extends along the outer peripheral surface of the upper end of the second lower engaging piece 321b and has a larger diameter than the second lower access hole 322b on the bottom surface of the second lower working space 324b. A second lower engaging flange 321pb to be caught may be further provided.

In addition, the positioning unit 300 is formed to protrude upward from the upper surface of the second lower engaging flange 321pb and has an outer peripheral surface facing the inner peripheral surface of the second lower support spring 323b. A second lower spring support rod 321db) may be further provided.

And, the positioning unit 300 is a second lower rod receiving groove ( 324gb) may be further provided.

In addition, the positioning unit 300 is recessed in a ring shape on the ceiling surface of the second lower working space 324b and is disposed concentrically with the second lower rod receiving groove 324gb and the second lower support spring 323b ) may further include a second lower spring seat groove (324sb) for supporting the upper end.

Here, the first upper engaging groove 315a and the second upper engaging groove 325a are formed on both sides of the upper rail groove 122, and the first lower engaging groove 315b and the second lower engaging groove 325b are It can be seen that the lower rail groove 123 is formed on both sides.

On the other hand, referring to FIG. 2 again, the first crystal piece 310 may be divided into equal parts along the direction of insertion into the upper rail groove 122 and the lower rail groove 123 .

In addition, the first crystal piece 310 has a first upper access hole 312a and a first lower access hole 312b that allow the first upper locking piece 311a and the first lower locking piece 311b to enter and exit. In addition, the first upper engaging piece (311a) and the first lower engaging piece (311b) may be equally divided along the entry and exit direction.

In addition, the first crystal piece 310 may divide the first upper working space 314a in which the first upper support spring 313a is accommodated along the direction in which the first upper support spring 313a is expanded and contracted.

In addition, the first crystal piece 310 may divide the first lower working space 314b in which the first lower support spring 313b is accommodated along the direction in which the first lower support spring 313b expands and contracts.

Meanwhile, referring to FIG. 2 again, the second crystal piece 320 may be divided into equal parts along the direction of insertion into the upper rail groove 122 and the lower rail groove 123 .

In addition, the first crystal piece 310 has a second upper access hole 322a and a second lower access hole 322b that allow the second upper locking piece 321a and the second lower locking piece 321b to enter and exit. In addition, the second upper engaging piece (321a) and the second lower engaging piece (321b) may be equally divided along the entry and exit direction.

In addition, the first crystal piece 310 may divide the second upper working space 324a in which the second upper support spring 323a is accommodated along the direction in which the second upper support spring 323a expands and contracts.

In addition, the first crystal piece 310 may divide the second lower working space 324b in which the second lower support spring 323b is accommodated along the direction in which the second lower support spring 323b expands and contracts.

That is, the divided structure of the first crystal piece 310 and the second crystal piece 320 as described above is divided into equal parts of the first crystal piece 310 and the second crystal piece 320 during later inspection or replacement of parts. It will be convenient because the structure can be separated to work.

Meanwhile, as shown in FIG. 5 , the installation unit 500 clamps the upper and lower surfaces of the first crystal piece 310 to move the first crystal piece 310 along the upper rail groove 122 and the lower rail groove 123 . It can be seen that the second crystal piece 320 slides along the upper rail groove 122 and the lower rail groove 123 by sliding the second crystal piece 320 by clamping the upper and lower surfaces of the second crystal piece 320 .

The installation unit 500 may largely include first and second clamping brackets 510 and 530 and first and second push blocks 520 and 540 .

First, the first clamping bracket 510 is a first upper contact bar 511 for clamping the upper surface of the first crystal piece 310 inserted from one end among both ends of the installation groove 121 of the positioning unit 300 . and a first lower contact bar 512 clamping the lower surface of the first crystal piece 310, and a first core body connecting the first upper contact bar 511 and the first lower contact bar 512 to each other ( 513) is provided.

In addition, the first push block 520 can slide and reciprocate through the first core body 513 , and contact the rear of the first crystal piece 310 to install the first crystal piece 310 into the installation groove 121 . The sliding insertion is performed along the upper rail groove 122 and the lower rail groove 123 formed on both sides.

In addition, the second clamping bracket 530 is a second upper contact bar 531 for clamping the upper surface of the second crystal piece 320 inserted from the other end among both ends of the installation groove 121 of the positioning unit 300 . and a second lower contact bar 532 clamping the lower surface of the second crystal piece 320, and a second core body connecting the second upper contact bar 531 and the second lower contact bar 532 to each other ( 533) is provided.

In addition, the second push block 540 can slide and reciprocate through the second core body 533 , and contact from the rear of the second crystal piece 320 to install the second crystal piece 320 into the installation groove 121 . The sliding insertion is performed along the upper rail groove 122 and the lower rail groove 123 formed on both sides.

On the other hand, the distance (L1, refer to FIG. 5 below) from the upper end of the inner surface of the first core body 513 to the end of the lower surface of the first upper contact bar 511 is such that the first upper engaging piece 311a can enter and exit. A distance of an imaginary line connecting the center of the first upper access hole 312a penetrating through the upper surface of the first crystal piece 310 and the center of the edge of the upper surface of the first crystal piece 310 (L2, see FIG. 4 below) It is equal to the length plus the radius L3 of the first upper access hole 312a (refer to FIG. 4 below).

Here, the rear end surface of the first push block 520 protrudes more than a distance L1 from the rear side surface of the first core body 513 to the push operation of the first push block 520 as in FIG. 6 . It will help without any hindrance.

On the other hand, the distance L1 from the lower end of the inner surface of the first core body 513 to the end of the upper surface of the first lower contact bar 512 is the first crystal piece ( The distance L2 of the imaginary line connecting the center of the first lower access hole 312b penetrating through the lower surface of the 310 and the center of the lower end edge of the first crystal piece 310, the first lower access hole 312b It is equal to the length plus the radius (L3) of

Here, the rear end surface of the first push block 520 protrudes more than a distance L1 from the rear side surface of the first core body 513 to the push operation of the first push block 520 as in FIG. 6 . It will help without any hindrance.

On the other hand, the distance L1 from the upper end of the inner surface of the second core body 533 to the end of the lower surface of the second upper contact bar 531 is the second crystal piece ( A distance L2 of an imaginary line connecting the center of the second upper access hole 322a formed through the upper surface of the second crystal piece 320 and the center of the upper end edge of the second crystal piece 320, and the second upper access hole 322a It is equal to the length plus the radius (L3) of

Here, the rear end surface of the second push block 540 protrudes more than a distance L1 from the rear side surface of the second core body 533 to the push operation of the second push block 540 as in FIG. 7 . It will help without any hindrance.

On the other hand, the distance L1 from the lower end of the inner surface of the second core body 533 to the end of the upper surface of the second lower contact bar 532 is the second crystal piece ( A distance L2 of an imaginary line connecting the center of the second lower access hole 322b formed through the lower surface of the second crystal piece 320 and the center of the lower end edge of the second crystal piece 320, and the second lower access hole 322b It is equal to the length plus the radius (L3) of

Here, the rear end surface of the second push block 540 protrudes more than a distance L1 from the rear surface of the second core body 533 to the push operation of the second push block 540 as shown in FIG. 7 . It will help without any hindrance.

Therefore, the operator makes the first locking piece 212 to be disposed at the center of the installation groove 121 and the upper and lower rail grooves 122 and 123 .

In this state, the operator is the first and second upper engaging pieces (311a, 321a) protruding from the upper and lower surfaces of the first and second crystal pieces (310, 320) as shown in FIGS. 6 (a) and 7 (a) and The first and second upper contact bars 511 and 531 so that the end surfaces of the first and second lower engaging pieces 311b and 321b are disposed on the same plane as the upper and lower surfaces of the first and second crystal pieces 310 and 320 6 (b) and 7 (b) by pressing with the sliding insert along the upper and lower rail grooves (122, 123).

Thereafter, when the distal ends of the first and second upper contact bars 511 and 531 come into contact with the pipe ram block 120 as shown in FIGS. 6 (b) and 7 (b), the first and second push blocks 520 and 540 ) penetrates the first and second core bodies 513 and 523 to attach the first and second crystal pieces 310 and 320 toward the side where the locking pieces 212 are disposed. The installation grooves 121 and the upper and lower rail grooves (122, 123) is pushed in.

Subsequently, the first and second upper engaging pieces 311a and 321a and the first and second lower engaging pieces 311b and 321b protrude from the upper and lower surfaces of the first and second crystal pieces 310 and 320 into which sliding is inserted. , respectively, the first and second upper engaging pieces 311a and 321a in the first and second upper engaging grooves 315a and 325a are engaged as shown in FIGS. 6(c) and 7(c), respectively, and the first and second lower As the first and second lower engaging pieces 311b and 321b engage with the engaging grooves 315b and 325b, the central arrangement of the installation groove 121 of the engaging piece 212 is completed.

As described above, the present invention provides a ram cylinder installation device for a pipe ram unit of a continuous water circulation system that enables efficient assembly and installation of parts for positioning after the rod is fastened when assembling the ram cylinder of the pipe ram unit It can be seen that this is done as a basic technical idea.

And, within the scope of the basic technical spirit of the present invention, many other modifications and applications are also possible for those of ordinary skill in the art.

100...pipe ram unit
110...pipe ram chamber body
120...pipe ram block
121...Installation Home
122...Upper rail groove
123...Lower rail groove
130...pipe ram packer
200...ram cylinder unit
210...load
211...joint neck
212...
220...piston
230...cylinder
300...positioning unit
310...The First Decision
310a...first contact cutout
311a...First upper catch piece
311b...First lower engaging piece
311da...First upper spring support rod
311db... First lower spring support bar
311pa...First upper latching flange
311pb...First lower latching flange
312a...First upper access hole
312b...First lower entrance hall
313a... first upper support spring
313b...First lower support spring
314a...First upper workspace
314b...First lower workspace
314ga...First upper rod receiving groove
314gb... First lower rod receiving groove
314sa...First upper spring seat groove
314sb.. 1st lower spring seat groove
315a... First upper locking groove
315b...First lower engaging groove
320...Second Decision
320a...second contact cutout
321a...Second upper catch piece
321b...Second lower engaging piece
321pa...Second upper latching flange
321pb...Second lower latching flange
321da...Second upper spring support rod
321db...Second lower spring support bar
322a...Second upper access hole
322b...Second lower entrance hall
323a...Second upper support spring
323b...Second lower support spring
324a...Second upper workspace
324b...Second lower workspace
324ga...Second upper rod receiving groove
324gb...Second lower rod receiving groove
324sa...Second upper spring seat groove
324sb...Second lower spring seat groove
325a...Second upper locking groove
325b...Second lower engaging groove
500...Mounting unit
510...1st clamping bracket
511...first upper contact bar
512...first lower contact bar
513...first core body
520...First push block
530...Second clamping bracket
531...Second upper contact bar
532...second lower contact bar
533...Second core body
540...Second push block

Claims (5)

a pipe ram block formed in the shape of a polygonal column and provided as many as the number of sides of the polygonal column so that a part or all of the inside of the pipe ram chamber body through which the drill pipe penetrates up and down can be accommodated;
a rod coupled along an installation groove recessed in the rear side of the pipe ram block and configured to move the pipe ram block closer or spaced apart toward an outer circumferential surface of the drill pipe passing through the pipe ram chamber body;
a positioning unit which is inserted from both ends of the installation groove and fixes the hooking pieces of the rod end inserted along the installation groove to be disposed in the center of the installation groove; and
It includes an installation unit detachably coupled to the positioning unit, and sliding the positioning unit from both ends of the installation groove by a predetermined distance so that the positioning unit is in contact with the left and right sides of the engaging piece,
The positioning unit,
A first crystal piece slidably inserted from one end of both ends of the upper rail groove and the lower rail groove respectively formed on both sides of the installation groove along the insertion direction of the positioning unit, the installation groove, the upper rail groove, and the lower part It includes a second crystal piece that is slidably inserted from the other end of both ends of the rail groove,
The locking piece is disposed between the distal end of each of the first crystal piece and the second crystal piece,
The installation unit clamps the upper and lower surfaces of the first crystal piece to slide the first crystal piece along the upper rail groove and the lower rail groove, and clamps the upper and lower surfaces of the second crystal piece to make the second crystal piece 2 A ram cylinder installation device for a pipe ram unit of a continuous water circulation system, characterized in that the crystal piece slides along the upper rail groove and the lower rail groove.
The method according to claim 1,
The pipe ram block is
The upper and lower sides of the installation groove are recessed in the rear side of the pipe ram block to communicate with the left and right side ends of the pipe ram block. an upper rail groove having a bottom surface formed on the same plane as the bottom surface of the installation groove;
A lower rail groove which is recessed downward from the connection part in contact with the bottom surface of the installation groove along the lower side of the upper and lower both sides of the installation groove, and has a bottom surface formed on the same plane as the bottom surface of the installation groove, further comprising and
The positioning unit is slidably coupled through both ends of the upper rail groove and the lower rail groove,
The length of an imaginary line perpendicular to the center of each of the upper rail groove and the lower rail groove at the same time and passing through the bottom surface of the installation groove is,
greater than or equal to the diameter or width of the distal end of the rod;
A coupling neck portion extending from the rod and having a diameter or width corresponding to the width of the installation groove and disposed concentrically with an imaginary line passing through the axial direction of the rod is disposed in the center of the installation groove,
An apparatus for installing a ram cylinder for a pipe ram unit of a continuous water circulation system, characterized in that an outer peripheral surface or an outer surface of the engaging piece extending from the end of the coupling neck is engaged with the upper rail groove and the lower rail groove.
delete The method according to claim 1,
The positioning unit,
a first upper engaging piece protruding so as to be able to enter and exit from an upper surface of the first crystal piece facing the upper rail groove;
a first upper engaging groove recessed upwardly in the upper rail groove to receive the first upper engaging piece;
a first lower engaging piece protruding so as to be able to enter and exit from a lower surface of the first crystal piece facing the lower rail groove;
a first lower engaging groove recessed downwardly in the lower rail groove to receive the first lower engaging piece;
a second upper engaging piece protruding so as to be able to enter and exit from an upper surface of the second crystal piece facing the upper rail groove;
a second upper engaging groove recessed upwardly in the upper rail groove to receive the second upper engaging piece;
a second lower engaging piece protruding so as to be able to enter and exit from a lower surface of the second crystal piece facing the lower rail groove;
It further comprises a second lower engaging groove recessed downwardly in the lower rail groove to receive the second lower engaging piece,
The installation unit is
The first crystal is clamped along the upper rail groove and the lower rail groove by clamping the end surfaces of each of the first upper locking piece and the first lower locking piece to be positioned on the same plane as the upper and lower surfaces of the first crystal piece. Insert the piece by sliding,
The second crystal is clamped along the upper rail groove and the lower rail groove by clamping so that an end surface of each of the second upper locking piece and the second lower locking piece is positioned on the same plane as the upper and lower surfaces of the second crystal piece. A ram cylinder installation device for a pipe ram unit of a continuous water circulation system, characterized in that the piece is inserted by sliding.
a pipe ram block formed in the shape of a polygonal column and provided as many as the number of sides of the polygonal column so that a part or all of the inside of the pipe ram chamber body through which the drill pipe penetrates up and down can be accommodated;
a rod coupled along an installation groove recessed in the rear side of the pipe ram block and configured to move the pipe ram block closer or spaced apart toward an outer circumferential surface of the drill pipe passing through the pipe ram chamber body;
a positioning unit which is inserted from both ends of the installation groove and fixes the hooking pieces of the rod end inserted along the installation groove to be disposed in the center of the installation groove; and
It includes an installation unit detachably coupled to the positioning unit, and sliding the positioning unit from both ends of the installation groove by a predetermined distance so that the positioning unit is in contact with the left and right sides of the engaging piece,
The installation unit is
A first upper contact bar clamping an upper surface of a first crystal piece inserted from one end of both ends of the installation groove of the positioning unit, a first lower contact bar clamping a lower surface of the first crystal piece, and the first upper contact a first clamping bracket having a first core body connecting the bar and the first lower contact bar to each other;
A first push block capable of reciprocating sliding through the first core body and slidingly inserting the first crystal piece along the upper rail groove and the lower rail groove formed on both sides of the installation groove by contacting from the rear of the first crystal piece. class,
A second upper contact bar clamping an upper surface of a second crystal piece inserted from the other end among both ends of the installation groove of the positioning unit, a second lower contact bar clamping a lower surface of the second crystal piece, and the second upper contact a second clamping bracket having a second core body connecting the bar and the second lower contact bar to each other;
A second push block capable of reciprocating sliding through the second core body and slidingly inserting the second crystal piece along the upper rail groove and the lower rail groove formed on both sides of the installation groove by contacting from the rear of the second crystal piece. A ram cylinder installation device for a pipe ram unit of a continuous water circulation system, characterized in that it comprises a.

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