CN214648948U - Device for putting multiple detectors into seabed mud synchronously - Google Patents

Abstract

The utility model discloses a throwing device for a plurality of detectors to synchronously feed mud into the seabed, which comprises a disc base, wherein four pieces of supporting angle steel with the same specification are welded at the lower part of the disc base, the tail end of the supporting angle steel is provided with a hanging ring base, a detachable hanging ring is arranged on the hanging ring base, one side of the hanging ring base is provided with a water depth meter base, and a water depth meter is arranged on the water depth meter base; four deep water electromagnetic valves are equally arranged on the disc base around the circle center, and the deep water electromagnetic valves are connected through a plurality of air inlet connecting pipes connected through three-way joints. Compared with the prior art, the utility model the advantage lie in: overall structure is simple practical, and spare part is selected, is connected and working method is reasonable, greatly reduced traditional equipment inconvenient practicality, the poor drawback of placement effect that brings in use, effectively improved detection efficiency and precision, the construction is simple and easy, goes into the visual steerable of mud state surface of water, used repeatedly, a device lays a plurality of disposable detectors.

Description

Device for putting multiple detectors into seabed mud synchronously

Technical Field

The utility model relates to an ocean detection equipment specifically indicates a device of puting in of mud is gone into to the synchronous seabed of a plurality of detectors.

Background

Oil and gas gathering and transportation is an important part of ocean oil and gas development and is the 'life line' of an offshore oil and gas production system. Once the submarine pipeline is damaged, oil gas leakage and serious consequences can be caused, so that the normal production of the offshore oil and gas field can be influenced, and huge economic loss is caused; more seriously, the oil gas leakage will cause serious pollution to the marine environment, destroy the marine ecology and also produce adverse social effects.

In order to monitor the safety state of the submarine pipeline in real time on line, in particular to the health monitoring of submarine pipeline leakage, a submarine detector which is small in size and can be buried is an effective scheme for monitoring. The using environment of the detector is considered as the burying state in the seabed soil in the exploration, so that the leakage signal can be effectively monitored, and the detector can be prevented from being invaded by external dangerous sources such as a cast trawl and the like on the seabed.

When the multiple detectors need to be buried in the mud at the same position at one time, the effect influence of the detectors on the buried depth is further researched, and therefore the buried device for synchronously burying the multiple detectors in the mud at the same position needs to be researched urgently.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is that current seabed detection device is because of the not enough in the design of relevant equipment function when actually putting in, leads to actually putting in that the effect is poor, put in inefficiency, causes the detection precision not good, has consumed a large amount of manpower and materials, unsatisfied present needs.

In order to solve the technical problem, the utility model provides a technical scheme does: a throwing device for synchronous seabed mud feeding of a plurality of detectors comprises a disc base, wherein four pieces of supporting angle steel with the same specification are welded on the lower portion of the disc base, a hanging ring base is arranged at the tail end of the supporting angle steel, a detachable hanging ring is mounted on the hanging ring base, a water depth meter base is arranged on one side of the hanging ring base, and a water depth meter is mounted on the water depth meter base; four deep water electromagnetic valves are arranged on the disc base in equal parts around the circle center, the deep water electromagnetic valves are connected through a plurality of air inlet connecting pipes connected through tee joints, and one of the tee joints is selected as an initial end connector for being externally connected with a high-pressure hose for supplying air; a cable junction box is arranged on the disc base, and an underwater tilt sensor is additionally arranged at the edge of the disc base;

the disc base is internally provided with a straight spray pipe, three side spray pipes are welded outside the straight spray pipe, a spray pipe body consisting of the straight spray pipe and the side spray pipes is connected with the disc base through a fixed base plate, three protection and separation shells are additionally arranged on the spray pipe body from top to bottom, each protection and separation shell comprises a side flat plate, the upper part of each side flat plate is connected with a top oblique conical plate through a top limiting plate, the lower part of each side flat plate is connected with a bottom oblique conical plate through a bottom supporting plate, the upper part of each top oblique conical plate is additionally provided with a top cover plate, and the lower part of each bottom oblique conical plate is additionally provided with a bottom cover plate; an extension torsion steel sheet is additionally arranged on the outer side of the side flat plate through a bolt, and the tail part of the extension torsion steel sheet is connected with a torsion spring piece through a bolt; a detector is additionally arranged in the protection and separation shell;

the side spray pipe is provided with a side spray hole, the deep water electromagnetic valve directly controls the switch of the straight spray pipe and the side spray pipe, high-pressure gas is sprayed out from the side spray hole, and the detector is under the thrust action of the high-pressure gas sprayed out from the side spray hole, so that the detector passes through and is separated from the whole device.

Compared with the prior art, the utility model the advantage lie in: overall structure is simple practical, and spare part is selected, is connected and working method is reasonable, greatly reduced traditional equipment inconvenient practicality, the poor drawback of placement effect that brings in use, effectively improved detection efficiency and precision, the construction is simple and easy, goes into the visual steerable of mud state surface of water, used repeatedly, a device lays a plurality of disposable detectors.

As an improvement, the upper stream of the deepwater electromagnetic valve is connected with the air inlet connecting pipe and the tee joint by adopting a sealing connecting pipe, and the lower stream of the deepwater electromagnetic valve is connected with the straight jet pipe and the side jet pipe by adopting a sealing connecting pipe.

As an improvement, the torsion spring plate provides the function of a single-phase switch, and opens a path separated from the whole device when the detector is pushed by high-pressure gas of the side spray hole.

As an improvement, the side spray pipe comprises a A, B, C three-marked pipe body, and the side spray holes are respectively an A side spray hole, a B side spray hole and a C side spray hole; the side surface of the straight spray pipe is not provided with a side spray hole, and only the bottom of the straight spray pipe is provided with a D spray hole.

As an improvement, the side spray holes of the three side spray pipes are all arranged in the outward radial direction when being installed.

As a modification, three protection and separation housings are provided at vertical heights of 0.5m, 1m and 2m downward from the disc base, respectively.

Drawings

Fig. 1 is a schematic structural diagram of a throwing device for synchronously throwing seabed mud by a plurality of detectors.

Fig. 2 is a schematic structural view of an enlarged region a.

Fig. 3 is a structural schematic diagram of a protection and separation shell of a throwing device for synchronous seabed mud feeding of a plurality of detectors in a top view state.

Fig. 4 is a schematic diagram of the installation position of a torsion spring plate of a throwing device for synchronously throwing the mud into the seabed by a plurality of detectors.

Fig. 5 is a schematic structural diagram of a plurality of detectors in a top view of a straight nozzle and a side nozzle of the device for synchronously throwing the seabed mud.

Fig. 6 is a schematic orientation of three protection and separation housings of a multi-detector synchronous seabed mud feeding throwing device in a top view.

Fig. 7 is a schematic structural diagram of a multi-detector synchronous seabed mud-entering throwing device in a top view state.

Fig. 8 is a schematic structural diagram of a throwing device for synchronous seabed mud feeding by a plurality of detectors in an operating state.

Fig. 9 is a schematic structural view of an enlarged region B.

As shown in the figure: 1. a fixed base plate, 2, a cable junction box, 3, a deep water electromagnetic valve, 4, an underwater inclination angle sensor, 5, support angle steel, 6, a detachable lifting ring, 7, a bathometer, 8, a lifting ring base, 9, a bathometer base, 10, a disk base, 11, a straight spray pipe, 12, a side spray pipe, 13, a protection and separation shell, 14, a top inclined conical plate, 15, a side spray hole, 16, a side flat plate, 17, a bottom inclined conical plate, 18, a top cover plate, 19, a top limiting plate, 20, a detector, 21, an outer extension torsion steel sheet, 22, a bottom support plate, 23, a bottom cover plate, 24, a torsion spring plate, 25, an A side spray hole, 26, a B side spray hole, 27, a C side spray hole, 28, D straight spray hole, 29, a sealing connecting pipe, 30, a tee joint, 31, an air inlet connecting pipe, 32, a pressure transmitter, 33, a crane, 34, a high-pressure underwater hose, 35, a cable, 36 and a detector cable, 37. boat, 38, water surface, 39, mud surface.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The utility model discloses when the concrete implementation, a putting device of synchronous seabed income mud of a plurality of detectors, including disc base 10, the welding of disc base 10 lower part has four the same specification support angle steel 5, and the support angle steel 5 end is equipped with rings base 8, the rings base 8 is last to install detachable rings 6, rings base 8 one side is equipped with depth of water meter base 9, install depth of water meter 7 on depth of water meter base 9 additional; four deep water electromagnetic valves 3 are additionally arranged on the disc base 10 in equal parts around the circle center, the deep water electromagnetic valves 3 are connected through air inlet connecting pipes 31 connected through a plurality of tee joints 30, and one of the tee joints 30 is selected as an initial end joint for externally connecting a high-pressure hose for air supply; the disc base 10 is provided with a cable junction box 2, and the edge of the disc base 10 is additionally provided with an underwater tilt angle sensor 4;

a straight spray pipe 11 is installed in the disc base 10, three side spray pipes 12 are welded outside the straight spray pipe 11, a spray pipe body formed by the straight spray pipe 11 and the side spray pipes 12 is connected with the disc base 10 through a fixed base plate 1, the spray pipe body is provided with three protection and separation shells 13 from top to bottom, each protection and separation shell 13 comprises a lateral flat plate 16, the upper part of each lateral flat plate 16 is connected with a top inclined conical plate 14 through a top limiting plate 19, the lower part of each lateral flat plate 16 is connected with a bottom inclined conical plate 17 through a bottom supporting plate 22, the upper part of each top inclined conical plate 14 is provided with a top cover plate 18, and the lower part of each bottom inclined conical plate 17 is provided with a bottom cover plate 23; an extension torsion steel sheet 21 is additionally arranged on the outer side of the side flat plate 16 through a bolt, and the tail part of the extension torsion steel sheet 21 is connected with a torsion spring piece 24 through a bolt; a detector 20 is additionally arranged in the protection and separation shell 13;

the side spray pipe 12 is provided with a side spray hole 15, the deep water electromagnetic valve 3 directly controls the switch of the straight spray pipe 11 and the side spray pipe 12, high-pressure gas is sprayed out from the side spray hole 15, and the detector 20 is under the thrust action of the high-pressure gas sprayed out from the side spray hole 15, so that the detector 20 is separated from the whole device.

The upper stream of the deep water electromagnetic valve 3 is connected with an air inlet connecting pipe 31 and a tee joint 30 by adopting a sealing connecting pipe 29, and the lower stream is connected with the straight spray pipe 11 and the side spray pipe 12 by adopting the sealing connecting pipe 29.

The torsion spring 24 provides a single phase switch function, which opens the way out of the whole device when the detector 20 is pushed by the high pressure gas from the side jet hole 15.

The side spray pipe 12 comprises A, B, C three marked pipe bodies, and the side spray holes 15 are respectively an A side spray hole 25, a B side spray hole 26 and a C side spray hole 27; the side spray hole 15 is not arranged on the side surface of the straight spray pipe 11, and only one D direct spray hole 28 is arranged at the bottom.

The side spray holes 15 of the three side spray pipes 12 are all arranged in the outward radial direction when being installed.

The three protection and separation housings 13 are respectively provided at vertical heights of 0.5m, 1m and 2m downward from the disc base 10.

The utility model discloses a theory of operation: the device consists of a disc base, support angle steel, a lifting ring base, a depth gauge base, a cable junction box, a fixing buckle, an underwater tee joint, an air inlet connecting pipe, an air leakage connecting pipe, a deep water electromagnetic valve, a fixing base plate, a straight spray pipe, a side spray pipe, a leak hole and a protection and separation shell. Wherein the protection and separation casing includes: the side panel, the top cover plate, the bottom cover plate, the top limit plate, the bottom support plate, the outward-extending torsion steel sheet, the torsion spring piece and other parts.

The angle steel support welded around the disc base, the straight spray pipe and the side spray pipe form an integral device frame. A lifting ring base, a water depth meter base, a cable junction box and a deep water electromagnetic valve are arranged on the base disc. The straight spray pipe and the side spray pipe are welded together and are connected with the base plate through the fixed base plate. The upper stream of the deep water electromagnetic valve is connected with an air inlet hose/tee joint by adopting a connecting pipe, and the lower stream of the deep water electromagnetic valve is connected with a straight spray pipe and a side spray pipe by adopting a connecting pipe. The electromagnetic valve can control the on-off of the 4 nozzles. The positions of 3 side spray pipes which are radially outward and are downward-0.5 m, -1m and-2 m away from the base plate are provided with a protection and separation shell. The main function of the shell is to protect the detector during the process of entering mud and sinking, and to separate the device from the detector mud when reaching a predetermined depth. The upper cover plate and the lower cover plate are arranged in a slope shape to reduce sinking resistance so as to facilitate sinking construction. The torsion spring piece provides a single-phase switch, and when the detector is pushed by high-pressure gas of the side spray hole, the detector can smoothly pass through the device to be separated from the device.

When the device is used, related parts such as a sling, a detector, a depth gauge, a pressure transmitter, an inclination angle sensor, an electromagnetic valve connecting wire, a high-pressure hose and the like are installed and debugged on a ship. The crane lowers the device to the seabed, the spray pipe touches mud, and the underwater sensor attitude and the inclination angle are observed on the water surface. After the device is steady, adjustment air supply pressure observes pressure transmitter numerical value, treats to reach the predetermined value after, opens D solenoid valve, and high-pressure gas passes through high-pressure flexible hose, tee bend, air inlet connection pipe, solenoid valve, gas leakage connecting pipe, straight spray tube under water, directly spouts the hole blowout through D, and the downside soil body is strikeed to the high pressure, makes the soil body not hard up. The device slowly sinks by its own weight.

In the sinking process, the attitude inclination angle of the water surface monitoring device needs to be less than 10 degrees, and when the attitude inclination angle exceeds 10 degrees, two adjustment schemes can be adopted. Firstly, the crane lifts the device and resumes the inclination, closes D solenoid valve, increases air supply pressure, waits to reach higher grade pressure value, opens D solenoid valve again, strikes the downside soil body. And secondly, replacing the residual gas in the high-pressure hose with water, and then pushing the water again by adopting a high-pressure gas source to enable the D-shaped direct injection hole to spray out the hydraulic cutting type water to impact the soil body on the lower side. The posture inclination angle of the device is kept to be larger than 10 degrees at the moment of the whole process, and the two schemes can be repeatedly carried out.

When the device reaches the set depth, the detector can be separated. When the pressure transmitter reaches a set value, the solenoid valve No. C is opened firstly, high-pressure gas is sprayed out through the side spray hole No. C, the gas is gathered in the protection and separation shell, the detector is pushed to move horizontally to push away the torsion spring, and separation of the detector is achieved. And the operation of separating the detectors B and A is carried out in sequence in the same way.

After the separation operation is finished, the recovery device can be selected according to the field situation. When the device is recovered, the electromagnetic valve No. D is selectively opened according to the condition, so that the soil around the spray pipe is loosened by the bubbles, and the device is quickly lifted and recovered.

The device adopts a remote control underwater device, utilizes the high-pressure cutting principle and the self-weight sinking principle of jet logistics to carry out mud entering construction, and is simple and easy to implement. Through ingenious setting of the protection and separation shell, large-scale marine equipment and artificial diving with high danger coefficient can be omitted.

In view of repeated use in seawater, the components are made of stainless steel materials to reduce seawater corrosion. The connection of the related components and the wiring of the cable need special treatment, so that high-pressure watertight and gas-liquid-tight are ensured.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature, and in the description of the invention, "plurality" means two or more unless explicitly specifically defined otherwise.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may include, for example, fixed connections, detachable connections, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the present disclosure, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact between the first and second features, or may comprise contact between the first and second features not directly. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly above and obliquely above the second feature, or simply meaning that the first feature is at a lesser level than the second feature.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Although embodiments of the present invention have been shown and described, it is to be understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that changes, modifications, substitutions and alterations can be made to the above embodiments by those of ordinary skill in the art without departing from the principles and spirit of the present invention.

Claims (6)

1. The utility model provides a synchronous seabed of a plurality of detectors is gone into throwing device of mud, includes disc base (10), its characterized in that: four supporting angle steels (5) with the same specification are welded on the lower portion of the disc base (10), a hanging ring base (8) is arranged at the tail end of each supporting angle steel (5), a detachable hanging ring (6) is mounted on each hanging ring base (8), a water depth meter base (9) is arranged on one side of each hanging ring base (8), and a water depth meter (7) is additionally arranged on each water depth meter base (9); four deep water electromagnetic valves (3) are arranged on the disc base (10) in equal parts around the circle center, the deep water electromagnetic valves (3) are connected through air inlet connecting pipes (31) connected by a plurality of tee joints (30), and one of the tee joints (30) is selected as a starting end joint for being externally connected with a high-pressure hose for air supply; the cable junction box (2) is arranged on the disc base (10), and the underwater tilt angle sensor (4) is additionally arranged at the edge of the disc base (10);

a straight spray pipe (11) is installed in the disc base (10), three side spray pipes (12) are welded outside the straight spray pipe (11), a spray pipe body formed by the straight spray pipe (11) and the side spray pipes (12) is connected with the disc base (10) through a fixed base plate (1), three protection and separation shells (13) are installed on the spray pipe body from top to bottom, each protection and separation shell (13) comprises a lateral flat plate (16), the upper portion of each lateral flat plate (16) is connected with a top oblique conical plate (14) through a top limiting plate (19), the lower portion of each lateral flat plate is connected with a bottom oblique conical plate (17) through a bottom supporting plate (22), a top cover plate (18) is installed on the upper portion of each top oblique conical plate (14), and a bottom cover plate (23) is installed on the lower portion of each bottom oblique conical plate (17); an extension torsion steel sheet (21) is additionally arranged on the outer side of the side flat plate (16) through a bolt, and the tail of the extension torsion steel sheet (21) is connected with a torsion spring piece (24) through a bolt; a detector (20) is additionally arranged in the protection and separation shell (13);

the side spray pipe (12) is provided with a side spray hole (15), the deep water electromagnetic valve (3) directly controls the switch of the straight spray pipe (11) and the side spray pipe (12), high-pressure gas is sprayed out from the side spray hole (15), and the detector (20) is under the thrust action of the high-pressure gas sprayed out from the side spray hole (15), so that the detector (20) passes through and is separated from the whole device.

2. A throwing device for synchronous seabed mud feeding of a plurality of detectors according to claim 1, wherein: the upper stream of the deepwater electromagnetic valve (3) is connected with an air inlet connecting pipe (31) and a tee joint (30) by adopting a sealing connecting pipe (29), and the lower stream of the deepwater electromagnetic valve is connected with a straight spray pipe (11) and a side spray pipe (12) by adopting the sealing connecting pipe (29).

3. A throwing device for synchronous seabed mud feeding of a plurality of detectors according to claim 1, wherein: the torsion spring (24) plays a role of a single-phase switch, and opens a path separated from the whole device when the detector (20) is pushed by high-pressure gas of the side spray hole (15).

4. A throwing device for synchronous seabed mud feeding of a plurality of detectors according to claim 1, wherein: the side spray pipe (12) comprises a A, B, C three-marked pipe body, and the side spray holes (15) are respectively an A side spray hole (25), a B side spray hole (26) and a C side spray hole (27); the side surface of the straight spray pipe (11) is not provided with a side spray hole (15), and only the bottom is provided with a D straight spray hole (28).

5. A throwing device for synchronous seabed mud feeding of a plurality of detectors according to claim 1, wherein: the side spray holes (15) of the three side spray pipes (12) are all arranged in the outward direction in a radial mode when being installed.

6. A throwing device for synchronous seabed mud feeding of a plurality of detectors according to claim 1, wherein: the three protection and separation shells (13) are respectively arranged at the positions which are 0.5m, 1m and 2m from the downward vertical height of the disc base (10).

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