KR101358123B1 - Valve assembly of mud pump for mud circulation system - Google Patents

Abstract

A valve assembly for preventing overpressure of a mud pump for a mud circulation system is disclosed. The valve assembly according to the present embodiment includes a valve body coupled to the mud pump and having a flow passage therein, and an overpressure preventing device connected to the valve body so as to communicate with the flow passage, the flow passage including a first flow passage communicating with the mud pump. And a second flow passage communicating with the first flow passage, a third flow passage, and a fourth flow passage, wherein the overpressure preventing device includes a pressure safety valve (PSV) connected to any one of the second to fourth flow passages, and a second flow passage. By providing a bleed valve connected in communication with the other of the fourth to fourth passages, and a pressure transmitter connected to the other of the second to fourth passages to provide a valve assembly with improved reliability and space utilization.

Description

Valve assembly of mud pump for mud circulation system {VALVE ASSEMBLY OF MUD PUMP FOR MUD CIRCULATION SYSTEM}

The present invention relates to a valve assembly for preventing overpressure of a mud pump pumping to circulate mud in a mud circulation system.

In general, a drill ship is a drilling ship that is equipped with drilling equipment suitable for the development of subsea oil fields, etc., to discover crude oil and gas at sea, and to sail with its own power.

Figure 1 schematically shows a conventional general drilling drilling process. As shown in FIG. 1, the drillship 1 and the seabed 2 are connected by a riser 3 and are drilled into the seabed to drill seabed resources stored in an oil well located on a rock below the seabed. A casing pipe 4 having a large diameter is located, and a drill pipe 5 connected to the drill ship 1 is provided inside the casing pipe 4. The drill bit 6 is provided at the end of the drill pipe 5.

On the other hand, the drill ship 1 is provided with a mud circulation system 10 for supplying a mud to the drill bit (6). The mud circulation system 10 is provided with a mud tank 11 in which the mud is stored, and a mud pump 13 for pumping the mud stored in the mud tank 11 and feeding the mud tank 11 into the drill pipe 5.

The mud supplied by the mud pump 13 is fed to the rotating ring 15 through the inlet line 14 and then moved downward through the inside of the cali 16 and the drill pipe 5 to the drill bit 6. The mud discharged from the drill bit 6 is mixed with the rock broken by the drill bit 6 and then ascended through the space between the casing pipe 4 and the drill pipe 5 to carry out the recovery line 17. Through the mud tank 11 is stored again and then reused.

On the other hand, between the mud pump 13 and the mud tank 11, in order to prevent the overpressure applied to the mud pump 13, as shown in Figure 2 (Pressure Safety Valve: PSV, 21) and the bleed valve A pipeline 20 in which a bleed valve 22 is installed is installed.

The pressure relief valve 21 is installed in the pipeline 20, and the bleed valve 22 is provided in the bypass line 25 connecting the pipeline 20 at the inlet side and the outlet side of the pressure safety valve 21. It is installed by flange coupling.

Due to this structure, the pressure safety valve 21 should be installed spaced apart from the mud pump 13 by a predetermined distance (1 to 2 m). Therefore, the operation reliability of the pressure safety valve 21 is reduced due to the pressure drop by the pipeline 20. There is a problem of deterioration. In addition, when the pressure safety valve 21 and the bleed valve 22 are installed, the work of installing the valves 21 and 22 in the pipeline 20 becomes complicated (additional materials, welding work, etc.). Since the strength test to determine whether or not to withstand the set pressure must be performed, there is a problem that the productivity is reduced due to the increase in cost and installation time.

An embodiment of the present invention provides a valve assembly for preventing overpressure of a mud pump that can improve the reliability and simplify the installation work in the mud circulation system.

The valve assembly of the mud pump system for mud circulation system according to an aspect of the present invention, in the valve assembly of the mud pump system for mud circulation to prevent overpressure of the mud pump for supplying the mud to the drilling apparatus, is coupled to the mud pump A valve body having a flow path therein and an overpressure preventing device connected to the valve body to communicate with the flow path, wherein the flow path includes a first flow path communicating with the mud pump and a second flow path communicating with the first flow path; And a third passage and a fourth passage, wherein the overpressure preventing device includes a pressure safety valve (PSV) connected in communication with any one of the second through fourth passages, and the other of the second through fourth passages. And a bleed valve connected in communication with the pressure transmitter, and a pressure transmitter connected in communication with the other one of the second to fourth flow paths.

In addition, the first passage of the valve body may be connected to the mud pump through a flange coupling.

In addition, the valve assembly may be integrally formed in one block.

In addition, the outlet of the pressure safety valve is connected to the mud tank, and when the pressure safety valve is opened due to the overpressure of the mud, the mud may be discharged to the mud tank through the outlet of the pressure safety valve.

The valve assembly of the mud pump system for the mud circulation system of the present embodiment can minimize the influence of the pressure drop of the mud during the operation of the valve to improve the operation reliability of the valve assembly.

In addition, as the valve assembly of the mud circulation system mud pump of the present embodiment is installed in one block, not only the space utilization is increased, but also the productivity of the pipe material cost is reduced and the installation is simplified.

1 schematically illustrates a drilling process in a conventional general drill ship.
Figure 2 shows the installation structure of the valve assembly for preventing the overpressure of the conventional mud pump.
3 schematically shows a mud circulation system according to an embodiment of the present invention.
Figure 4 shows a state in which the valve assembly is installed on the mud pump according to an embodiment of the present invention.
Figure 5 shows a state in which the valve assembly is installed in the mud pump according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Figure 3 schematically shows a mud circulation system according to an embodiment of the present invention, Figure 4 shows a state in which the valve assembly is installed in the mud pump according to an embodiment of the present invention.

Referring to FIG. 3, the mud circulation system according to the present embodiment includes a drilling device 30, a mud pump 40 for supplying a mud to the drilling device 30, and a mud returned from the drilling device 30. It includes a mud tank (50) for storing.

The drilling device 30 has a drill pipe 32 which enters into a borehole 31 cut out into the seabed. A drill bit 32a is connected to a lower end of the drill pipe 32, and a kelly 33 and a swivel 34 are sequentially connected to the upper end. The rotary ring 34 rotates the calli 33 and the drill pipe 32.

The rotary ring 34 is connected to the discharge line 41 of the mud pump 40 pumping the mud stored in the mud tank 50 through the rotary hose 35 and the stand pipe 36.

The mud, which lubricates the drill bit 32a, is a mud-pit made of bentonite and colloidal clay dissolved in water or fuel.

The mud tank 50 is connected to the mud pump 40 by the suction line 42. In addition, the mud tank 50 is connected to the drilling device 30 through a recovery line 43 in which the mud is recovered from the drilling device 30.

The mud tank 50 is a shale shaker 51 for removing the rock, sand and gas contained in the mud delivered through the recovery line 43 to regenerate the mud, and a sand remover (desander) ( 52, a mud regeneration system including a desilter 53, a degasser 54, and the like.

Through this configuration, the mud stored in the mud tank 50 is introduced into the drilling device 30 by the pumping force of the mud pump 40. Drilling fluid introduced into the drill pipe 32 through the rotary ring 34 and the calli 33 is discharged through the drill bit 32a to perform the lubrication of the drill bit 32a, and the borehole 31. And is moved upward through the annular space formed between the drill pipe 32 and discharged to the recovery line 43.

The mud that flows into the mud tank 50 through the recovery line 43 is removed through the shale shaker 51, the large particles of rock is removed, the various mud, sand, oil and gas by the mud regeneration system The mud regenerated through the filtering process is stored in the mud tank 50.

The mud stored in the mud tank 50 is again pumped by the mud pump 40 and transferred to the drilling apparatus 30 for circulation.

On the other hand, the mud pump 40 is in a high pressure state because it provides a pumping force for circulating the mud in the mud circulation system. When the set pressure is exceeded to prevent damage due to the overpressure of the mud pump 40, a valve assembly 60 for ejecting the mud is provided.

4 is a view illustrating a valve assembly installed to prevent overpressure of a mud pump according to an exemplary embodiment of the present invention.

Referring to FIG. 4, the valve assembly 60 includes a valve body 61 coupled to a high pressure pipe 45 of a mud pump 40 through which a high pressure mud flows, and overpressure preventing devices coupled to the valve body 61. (81,82,83) can be formed integrally in one block.

The valve body 61 has a flange 62 coupled to the flange 46 formed on the high pressure pipe 45 of the mud pump 40 on one side, and the overpressure preventing devices 81, 82, 83 on the other side Installation units 63, 64, and 65 to be installed may be provided to have an approximately cross-shaped appearance.

In the valve body 61, flow paths 66, 67, 68, and 69 are formed to communicate with each other so that the mud flows through the installation parts 63, 64, and 65. The flow paths 66, 67, 68, and 69 are disposed to face each other by being bent in a direction crossing the first flow path 66 and the first flow path 66 where the high pressure mud flows in communication with the mud pump 40. And a second flow path 67 and a third flow path 69, and a fourth flow path 68 positioned opposite the first flow path 66.

The overpressure preventing devices 81, 82, and 83 are automatically opened when the mud flowing in the flow paths 66, 67, 68, and 69 exceeds the set pressure so that the mud is ejected to release the overpressure. When the pressure is less than or equal to the pressure safety valve (PSV) (81) to be restored to its normal state, and the inside of the mud pump 40 to flush (flush) or discharge the mud remaining inside the mud pump 40 A bleed valve 82 used at the time and a pressure transmitter 83 for detecting and transmitting the pressure of the mud flowing in the flow path (66, 67, 68, 69).

The pressure safety valve 81 is coupled to the first installation portion 67 to communicate with the second flow passage 67, and the bleed valve 82 is connected to the second installation portion 65 to communicate with the third flow passage 69. The pressure transmitter 83 may be coupled to the third installation unit 64 so as to communicate with the fourth flow passage 68.

The outlet of the pressure relief valve 81 is connected to the mud tank 50 through the blowing line 70 as shown in FIG.

The signal detected by the pressure transmitter 83 is transmitted to a control system (not shown), and the control system remotely controls the mud pump 40 according to the signal transmitted by the pressure transmitter 83.

In the present embodiment, the pressure safety valve 81, the bleed valve 82, and the pressure transmitter 83 are installed to communicate with the second flow passage 67, the third flow passage 69, and the fourth flow passage 68, respectively. 5, the pressure safety valve 81 and the pressure transmitter 83 may be installed to communicate with the fourth flow passage 68 and the second flow passage 67, respectively. That is, the positions of the overpressure preventing devices 81, 82, 83 provided in the flow paths 67, 68, and 69 are not limited. This is because the flow paths 67, 68, and 69 are formed to communicate with each other, so that the operation of the respective overpressure preventing devices 81, 82, and 83 is not limited.

Through the structure of the valve assembly 60, the pressure safety valve 81 when the pressure inside the mud pump 40 exceeds the set pressure due to external factors such as external fire, malfunction of the equipment, change of atmospheric pressure, etc. Is opened to release the pressure of the mud to prevent damage to the mud pump 40. In addition, even if the pressure safety valve 81 malfunctions, the internal pressure of the mud pump 40 can be ejected by the bleed valve 82, so that the reliability is further improved.

In addition, the valve assembly 60 for preventing the overpressure of the mud pump 40 is directly connected to the mud pump 40 through the valve body 61, the valve by using the existing pipe line (see Figure 2) Since the influence of the pressure drop can be minimized in comparison with the installed configuration, the reliability of the operation of the valves 81 and 82 is improved, as well as the pressure safety valve 81 and the bleed valve 82 in one valve body 61. ) And the pressure transmitter 83 is connected to increase the space utilization.

In addition, since the additional pipe line for installing the pressure safety valve 81, the bleed valve 82 and the pressure transmitter 83 is not necessary, productivity is improved due to a reduction in piping material costs and a shortening of installation time.

The foregoing has shown and described specific embodiments. However, the present invention is not limited only to the above embodiments, and those skilled in the art may make various changes without departing from the spirit of the technical idea of the invention as set forth in the claims below. will be.

30: drilling device, 40: mud pump,
41: discharge line, 42: suction line,
43: recovery line, 50: mud tank,
60: valve assembly, 61: valve body,
62: flange, 66: first euro,
67: Euro 2, 68: Euro 4,
69: third euro, 70: eruption line,
81: pressure relief valve, 82: bleed valve,
83: pressure transmitter.

Claims (4)

In the valve assembly of the mud pump for mud circulation system for preventing overpressure of the mud pump for supplying the mud to the drilling device,
A valve body coupled to the mud pump and having a flow path therein; And
It includes an overpressure preventing device connected to the valve body to communicate with the flow path,
The flow passage includes a first flow passage communicating with the mud pump, a second flow passage communicating with the first flow passage, a third flow passage and a fourth flow passage,
The overpressure preventing device includes a pressure safety valve (PSV) connected in communication with any one of the second to fourth flow passages, a bleed valve connected in communication with another one of the second to fourth flow passages, and the second The valve assembly of the mud pump for mud circulation system comprising a pressure transmitter connected in communication with the other of the fourth passage. The method of claim 1,
The first passage of the valve body is a valve assembly of the mud pump for mud circulation system is connected to the mud pump through a flange coupling. The method of claim 1,
The valve assembly is a valve assembly of the mud pump system for mud circulation is formed integrally in one block. The method of claim 1,
The outlet of the pressure relief valve is connected to the mud tank,
And the mud is discharged to the mud tank through the outlet of the pressure safety valve when the pressure safety valve is opened due to the overpressure of the mud.

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