CN210863020U - Submarine sediment pressure observation device - Google Patents

Abstract

The utility model discloses a submarine sediment pressure observation device, which belongs to the technical field of submarine detection, and comprises a probe rod, a conical tip, a reference pressure cylinder and a probe, wherein the probe rod is hollow to form a holding cavity and comprises a plurality of section rods which are connected with each other; the conical tip is arranged at one end of the probe rod; the reference pressure cylinder is arranged at the other end of the probe rod and comprises a cylinder body, an oil bag positioned in the cylinder body and a plug connected with the cylinder body in a sliding manner, and the plug selectively seals the cylinder body so as to enable the oil bag to provide constant pressure; the probe is arranged at the joint of the adjacent section bars and comprises a shell and a differential pressure sensor, a first channel communicated with the inner cavity of the oil sac is arranged in the shell, and the differential pressure sensor is used for detecting the differential pressure between the first channel and the outside. When the acting force of the soil body on the plug enables the plug to seal the barrel, the pressure in the first channel is hydrostatic pressure, and the mechanical state in the sediment can be detected under the condition that the influence of the depth of the seawater is avoided.

Description

Submarine sediment pressure observation device

Technical Field

The utility model relates to a submarine detection technical field especially relates to a submarine sediment pressure observation device.

Background

The change of the pore water pressure in the marine sediment is an important indicating parameter of the sediment strength change, and has a remarkable indicating function on the geological disaster phenomena such as sea wave and seabed landslide caused by earthquake. The action of earthquake and sea wave increases the pressure of pore water in the sediment, especially sand or silt, and reduces the effective stress supported by the sediment, thereby reducing the strength of the sediment. The stability of the deposit can be understood by the change in pore water pressure. Under the wave load, various mechanical states of the waves attached to the sediment can be known by observing the change of the pore water pressure in the sediment, so that technical support is provided for stability analysis. Therefore, observation of pore water pressure in the sediment under dynamic load is an important technical means in marine geotechnical engineering or marine geological disaster analysis.

The existing pore water pressure observation device is not only subjected to pore water pressure but also subjected to hydrostatic pressure in the use process, and the hydrostatic pressure is continuously improved along with the increase of the depth of seawater, so that a probe of the observation device used in deep sea needs to have a large measuring range, the resolution of the probe is reduced due to the increase of the measuring range, the sensitivity and the precision of the probe are reduced, and the accuracy of a measuring result is influenced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a submarine sediment pressure observation device to solve the too big technical problem of range that leads to the probe that receives the influence of sea water pressure that exists among the prior art.

As the conception, the utility model adopts the technical proposal that:

a seafloor sediment pressure observation device comprising:

the probe rod is hollow inside to form an accommodating cavity and comprises a plurality of section rods which are detachably connected;

the conical tip is arranged at one end of the probe rod;

the reference pressure cylinder is arranged at the other end of the probe rod and comprises a cylinder body, an oil bag positioned in the cylinder body and a plug connected with the cylinder body in a sliding manner, and the plug selectively seals the cylinder body so as to enable the oil bag to provide constant pressure;

the probe is arranged at the joint of the adjacent section rods and comprises a shell and a differential pressure sensor, a first channel communicated with the inner cavity of the oil sac is arranged in the shell, and the differential pressure sensor is used for detecting the differential pressure between the first channel and the outside.

The shell is internally provided with a mounting hole, the differential pressure sensor is arranged at the mounting hole, one end of the mounting hole is communicated with the first channel, and the other end of the mounting hole is communicated with the outside.

The shell is internally provided with a second channel and a pressure guide hole, the second channel is communicated with the containing cavity and the mounting hole, and the pressure guide hole is communicated with the containing cavity.

The pressure difference sensors are two types, namely a pore water pressure sensor and a soil pressure sensor, a permeable stone is arranged at the communication position of the pore water pressure sensor and the outside, and a stainless steel diaphragm is arranged at the communication position of the soil pressure sensor and the outside.

The oil bag comprises a barrel body, wherein a first opening and a second opening are formed in the barrel body, an inner cavity of the oil bag is communicated with the first opening, the first opening is communicated with a first channel through a pipeline, and the second opening is selectively plugged by a plug.

The plug comprises a main body part and limiting parts arranged at two ends of the main body part, the main body part is of a reducing structure and penetrates through the second opening, and the two limiting parts are respectively located on the inner side and the outer side of the barrel.

The end part of the plug is provided with a bottom contact rod, the bottom contact rod is located on the outer side of the barrel, and the bottom contact rod can push the plug to plug the barrel under the action of a soil body.

Wherein, still include the data acquisition subassembly, the data acquisition subassembly includes:

a circuit board;

the wire penetrates through the accommodating cavity, one end of the wire is connected with the circuit board, and the other end of the wire is connected with the differential pressure sensor.

The device comprises a probe rod, a conical tip, a reference pressure cylinder, a data acquisition assembly and a sealed cabin, wherein the sealed cabin is arranged at one end, far away from the conical tip, of the probe rod, and the reference pressure cylinder and the data acquisition assembly are both located in the sealed cabin.

The utility model has the advantages that:

the utility model provides a submarine sediment pressure observation device, because the oil bag is communicated with the first channel, the pressure in the first channel is equal to the pressure in the oil bag; when the device is placed in water, the plug is in an open state, the pressure in the first channel is equal to hydrostatic pressure, the pressure difference between the first channel and the outside is 0 at the moment, and the detection value of the pressure difference sensor is 0; the pressure value is detected by the pressure difference sensor in the probe along with the penetration of the cone tip into the soil body, and the detection value of the pressure difference sensor is the pressure difference at two ends due to the fact that one side of the pressure difference sensor is hydrostatic pressure, so that the influence of the hydrostatic pressure on the measurement of pressure parameters in the soil body is eliminated, and the measuring range of the probe can be reduced; when the plug contacts with the soil body, the acting force of the soil body on the plug enables the plug to seal the barrel, at the moment, the pressure in the first channel is not changed any more and is hydrostatic pressure, when waves, earthquakes and other loads act, the pore water pressure in the sediment changes (called super hydrostatic pressure), but the pressure in the first channel is still equal to the hydrostatic pressure, and the detection value of the differential pressure sensor is the super hydrostatic pressure, so that various mechanical states of different loads attached to the sediment can be detected in real time under the condition that the influence of the depth of seawater is avoided.

Drawings

Fig. 1 is a cross-sectional view of a device for observing the pressure of a sediment on the sea bottom according to an embodiment of the present invention;

fig. 2 is a cross-sectional view of a reference pressure cylinder of a device for observing the pressure of a sediment in the sea, according to an embodiment of the present invention;

fig. 3 is a cross-sectional view of a probe of a device for observing the pressure of a sediment in the sea bottom according to an embodiment of the present invention;

fig. 4 is a top view of a probe of a device for observing the pressure of a sediment in the sea bottom provided by the embodiment of the present invention;

FIG. 5 is a cross-sectional view taken along line A-A of FIG. 4;

FIG. 6 is a cross-sectional view taken along line B-B of FIG. 4;

fig. 7 is a cross-sectional view of a probe of a device for observing the pressure of a sediment in the sea bottom provided by the second embodiment of the present invention;

fig. 8 is a schematic diagram of a partial structure of a device for observing the pressure of a sediment on the sea bottom according to the second embodiment of the present invention.

In the figure:

1. a probe rod; 11. an accommodating cavity;

2. a conical tip;

3. a reference pressure cylinder; 31. a barrel; 32. an oil pocket; 33. a plug;

4. a probe; 41. a housing; 411. a first channel; 412. mounting holes; 413. a second channel; 414. a pressure guide hole; 42. a differential pressure sensor; 43. a permeable stone; 44. a stainless steel diaphragm;

5. a data acquisition component;

6. sealing the cabin;

7. a bottom contact rod.

Detailed Description

Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, unless expressly stated or limited otherwise, the terms "connected," "connected," and "fixed" are to be construed broadly, e.g., as meaning permanently connected, detachably connected, or integral to one another; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood in specific cases to 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 under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.

Example one

Referring to fig. 1 to 6, the embodiment of the present invention provides a device for observing the pressure of a sediment in the sea, which is required to penetrate into the sea bed when in use, so as to observe the force change in the sediment.

The device for observing the pressure of the seabed sediments comprises a probe rod 1, a conical tip 2, a reference pressure cylinder 3 and a probe 4, wherein the conical tip 2 is arranged at one end of the probe rod 1, and the reference pressure cylinder 3 is arranged at the other end of the probe rod 1. The inside cavity of probe rod 1 forms holding chamber 11, and probe rod 1 is including dismantling a plurality of section poles of connection, and probe 4 sets up in the junction of adjacent section pole. The reference pressure cylinder 3 comprises a cylinder body 31, an oil bag 32 positioned in the cylinder body 31 and a plug 33 slidably connected with the cylinder body 31, wherein the plug 33 selectively seals the cylinder body 31 to enable the oil bag 32 to provide constant pressure, the probe 4 comprises a shell 41 and a differential pressure sensor 42, a first channel 411 communicated with an inner cavity of the oil bag 32 is arranged in the shell 41, and the differential pressure sensor 42 is used for detecting the differential pressure between the first channel 411 and the outside.

Since the oil bag 32 communicates with the first passage 411, the pressure in the first passage 411 is equal to the pressure in the oil bag 32; when the plug 33 is placed in water, the plug 33 is in an open state, the pressure in the first channel 411 is equal to the hydrostatic pressure, and the pressure difference between the first channel 411 and the outside is 0 at this time, that is, the detection value of the pressure difference sensor 42 is 0; as the cone tip 2 penetrates into the soil body, the pressure difference sensor 42 in the probe 4 detects a pressure value, and one side of the pressure difference sensor 42 is hydrostatic pressure, so that the detection value of the pressure difference sensor 42 is the pressure difference between the two ends, and the influence of the hydrostatic pressure on the measurement of pressure parameters in the soil body is eliminated, so that the measuring range of the probe 4 can be reduced; when the plug 33 is in contact with the soil body, the acting force of the soil body on the plug 33 enables the plug 33 to seal the barrel 31, at this time, the pressure in the first channel 411 does not change any more and is hydrostatic pressure, when waves, earthquakes and other loads act, the pore water pressure in the sediment changes (called as super hydrostatic pressure), but the pressure in the first channel 411 is still equal to the hydrostatic pressure, and the detection value of the differential pressure sensor 42 is the super hydrostatic pressure, so that various mechanical states of different loads attached to the sediment can be detected in real time under the condition of not being influenced by the depth of the seawater. The pressure difference sensor 42 is mainly used for eliminating the influence of high seawater pressure and improving the measurement precision.

Because the soil body is of a layered structure, the mechanical parameters of each layer of soil body are different due to different properties of the soil body. In order to accurately measure the soil body, the probe 4 is provided with a plurality of rods, and the length of each rod can be selected according to the requirement. The awl point 2 sets up in probe rod 1's bottom, and awl point 2 can be directly be connected with the festival pole, also can set up a probe 4 between awl point 2 and the festival pole, and the one end and the festival pole of probe 4 are connected, and the other end and the awl point 2 of probe 4 are connected.

In this embodiment, the differential pressure sensor 42 is a pore water pressure sensor, the measured value is the pore water pressure, and the stability of the sediment can be known by detecting the change of the pore water pressure in real time. In a word, due to the adoption of differential pressure measurement, the accuracy of pore water pressure measurement can be improved, and reliable data is provided for the analysis of the properties of the submarine sediments based on the pore water pressure.

In order to transmit the data acquired by the differential pressure sensor 42, the data acquisition assembly 5 is further included, the data acquisition assembly 5 includes a circuit board and a lead, the lead is arranged in the accommodating cavity 11 in a penetrating manner, one end of the lead is connected with the circuit board, and the other end of the lead is connected with the differential pressure sensor 42. The data collected by the differential pressure sensor 42 is transmitted to the circuit board through a wire, and the circuit board is provided with a storage module for storing the data.

One end of the probe rod 1, which is far away from the cone tip 2, is provided with a sealed cabin 6, and the data acquisition assembly 5 is positioned in the sealed cabin 6 to protect the data acquisition assembly 5. The junction of the sealed cabin 6 and the probe rod 1 is provided with a threading hole, and a wire can enter the accommodating cavity 11 of the probe rod 1 through the threading hole. The capsule 6 needs to have a certain sealing and waterproof properties.

The sealed cabin 6 comprises a support plate connected with the probe rod 1 and a cover shell connected with the support plate, and the probe rod 1 is in threaded connection with the support plate. The area of backup pad is great, and its main effect provides the support counter-force after contacting with the soil body, prevents that probe rod 1 from excessively sinking.

In the reference pressure cylinder 3, a cylinder body 31 is provided with a first opening and a second opening, an inner cavity of the oil bag 32 is communicated with the first opening, the first opening is communicated with the first channel 411 through a pipeline, and the second opening is selectively blocked by a plug 33. The pipeline can enter the accommodating cavity 11 of the probe rod 1 through the threading hole and then extend to be communicated with the first channel 411. In this embodiment, a pipeline for communicating the oil bag 32 with the first passage 411 is made of a non-deformable tetrafluoride pipe.

The plug 33 includes a main body portion and limiting portions disposed at two ends of the main body portion, the main body portion is of a reducing structure and penetrates through the second opening, and the two limiting portions are located on the inner side and the outer side of the barrel 31 respectively. The main body portion has a smaller outer diameter on one side near the oil pocket 32 and a gradually larger outer diameter on the other side, and is aligned with the inner diameter of the second opening. The stopper portion is to prevent the plug 33 from falling out of the second opening.

For fixing the reference pressure cylinder 3, the reference pressure cylinder 3 is located in a sealed chamber 6. The cylinder 31 of the reference pressure cylinder 3 is connected with the side wall of the sealed cabin 6, the extending direction of the plug 33 is the same as that of the probe rod 1, and the plug 33 is arranged at the bottom of the cylinder 31 and faces downwards, so that the plug is convenient to contact with soil. During the process of deployment, the pressure of the oil bag 32 changes with the depth, and when the deployment stops, the plug 33 falls down, so that the pressure in the oil bag 32 is kept stable. After penetrating the soil mass, the soil mass acts on the plug 33, so that the plug 33 blocks the second opening.

In order to apply acting force to the plug 33 by soil, the end part of the plug 33 is provided with a bottom contact rod 7, and the bottom contact rod 7 is positioned on the outer side of the barrel 31 and extends out of the sealed cabin 6 to be in contact with the soil. When the sealed cabin 6 is in contact with the sea bed surface, the bottoming rod 7 moves upwards due to the upward acting force of the sea bed, the plug 33 is pushed to move upwards at the moment, the second opening is blocked, and therefore communication between the oil bag 32 and the external pressure is closed, and the pressure in the oil bag 32 is kept stable.

In this embodiment, the oil bag 32 is filled with airless water. When the plug 33 blocks the second opening, the pressure in the first channel 411 is kept unchanged, the influence of the fluctuating water pressure on the pressure in the first channel 411 is reduced, and the water in the first channel 411 is kept in a water-free state, so that the pressure is quickly transmitted to each probe 4. The oil bladder 32 functions to enclose the airless water and transmit the external pressure. When the pressure increases, the non-air water in the oil pocket 32 is compensated to the first passage 411 due to compressibility of the liquid.

In order to solve the problem that the seabed reference pressure is unstable due to the phenomena of settlement of the probe rod 1, seabed pressure fluctuation and the like, the oil sac is arranged to provide constant reference pressure, so that all measured outside pressures are guaranteed to have a stable reference value. The pressure difference sensor 42 and the reference pressure cylinder 3 are matched and cooperated to realize accurate measurement of the pressure of the seabed sediments.

In the probe 4, the shell 41 is in threaded connection with the probe rod 1, and a sealing ring is arranged between the shell 41 and the probe rod 1, so that sealing is realized, and the phenomenon that the real distribution rule of pore water pressure in sediment is influenced when pore water in the sediment enters the probe rod 1 is avoided. Joints are provided at both ends of the first passage 411, and the joints are screwed with the housing 41. The joint can be connected to a pipe so that the oil pocket 32 communicates with the first passage 411. The lower end of the first channel 411 of the bottommost probe 4 is plugged with a plug.

A mounting hole 412 is formed in the housing 41, the differential pressure sensor 42 is disposed at the mounting hole 412, one end of the mounting hole 412 is communicated with the first passage 411, and the other end of the mounting hole 412 is communicated with the outside, so that the differential pressure sensor 42 can detect the differential pressure between the first passage 411 and the outside. In this embodiment, a differential pressure sensor 42, which is a pore water pressure sensor, is provided on each probe 4. When the probe 4 penetrates the soil body and the plug 33 blocks the second opening, one side of the differential pressure sensor 42 bears hydrostatic pressure and the other side bears pore water pressure from the sediment. Because the differential pressure sensor 42 is a pore water pressure sensor, and the permeable stone 43 is arranged at the communication position of the mounting hole 412 and the outside, the pressure of water is not influenced to act on the differential pressure sensor 42, and the influence of sediment blocking on the differential pressure sensor 42 on the measurement precision can also be avoided. The number of differential pressure sensors 42 is not limited herein, and one differential pressure sensor 42 can be disposed in each mounting hole 412.

A second passage 413 is further disposed in the housing 41, and the second passage 413 is communicated with the accommodating chamber 11 and the mounting hole 412. Two ends of the second channel 413 are provided with watertight plugs, one end of each watertight plug is connected with a wiring of the differential pressure sensor 42 arranged in the second channel 413 in a penetrating manner, and the other end of each watertight plug is connected with a lead arranged in the accommodating cavity 11 in a penetrating manner. The lower end of the second passage 413 of the lowermost probe 4 is plugged.

The housing 41 is also provided therein with a pressure guide hole 414, and the pressure guide hole 414 communicates with the accommodation chamber 11. The main function of the pressure guide holes 414 is to transmit the seawater pressure to each probe rod 1, so as to prevent the probe rod 1 from being damaged by excessive external pressure. In the present embodiment, two pressure guide holes 414 are provided in the housing 41 of each probe 4, and the extending direction of the pressure guide holes 414 is along the axial direction of the probe 4.

When the device for observing the pressure of the sediment at the bottom of the sea is used, the device is firstly arranged, and after entering a soil body, the device can be observed in real time. Before the air is distributed, the air in the first channel 411, the pipeline and the oil bag 32 needs to be flushed out by the airless water, so as to ensure that the water in the first channel 411 is vacuum water as much as possible.

When the cloth is put on, the plug 33 is in an open state, the pressure in the first channel 411 is equal to the hydrostatic pressure, and the detection value of the differential pressure sensor 42 is 0. When the soil body touches the bottom, the pressure difference sensor 42 in the probe 4 detects a pressure value along with the penetration of the cone tip 2 into the soil body, and because one side of the pressure difference sensor 42 is hydrostatic pressure, the detection value of the pressure difference sensor 42 is the pressure difference at two ends, and the detection value of the pressure difference sensor 42 is the pore water pressure under the condition of not being subjected to external load; when the plug 33 contacts with the soil, the acting force of the soil on the plug 33 causes the plug 33 to close the second opening, and at this time, the pressure in the first channel 411 does not change any more, and is hydrostatic pressure. When waves, earthquakes and other loads act, the pore water pressure in the sediment changes, but the inside of the first channel 411 is still equal to the hydrostatic pressure, and the detection value of the differential pressure sensor 42 is the pore water pressure under the condition of external loads.

Example two

Fig. 7 and 8 show a second embodiment, wherein the same or corresponding parts as the first embodiment are provided with the same reference numerals as the first embodiment. For the sake of simplicity, only the differences between the second embodiment and the first embodiment will be described. The difference is that two types of differential pressure sensors 42, namely a pore water pressure sensor and a soil pressure sensor, are arranged on each probe 4, and the research on the mechanical state of the seabed sediments is further promoted by simultaneously measuring the pore water pressure and the soil pressure.

In this embodiment, the pore water pressure sensor and the soil pressure sensor are both provided with one, the mounting holes 412 are provided with two, namely a first mounting hole and a second mounting hole, the pore water pressure sensor is arranged in the first mounting hole, and the soil pressure sensor is arranged in the second mounting hole.

The permeable stone 43 is arranged at the communication position of the first mounting hole and the outside, so that the pressure of water is not influenced to act on the pore water pressure sensor, and the influence of sediment blocking on the pore water pressure sensor on the measurement precision can be avoided. A stainless steel diaphragm 44 is provided at a communication position of the second mounting hole with the outside. Stainless steel diaphragm 44 seals the second mounting hole and primarily functions to transmit the horizontal pressure exerted by the sediment to the soil pressure sensor. In order to ensure reliability, silicon oil is filled between the stainless steel diaphragm 44 and the soil pressure sensor.

The soil pressure is applied to the stainless steel diaphragm 44, so that the stainless steel diaphragm 44 deforms towards the inner side of the second mounting hole, the silicon oil between the soil pressure sensor and the stainless steel diaphragm 44 is squeezed, in order to keep the pressure balance, the pressure of the silicon oil rises to be equal to the soil pressure, at the moment, the silicon oil transmits the pressure to the soil pressure sensor, and the soil pressure is measured through the soil pressure sensor. Considering that the measured value of the soil pressure sensor is the pressure after the hydrostatic pressure is eliminated, the soil lateral pressure should be the soil pressure after the hydrostatic pressure is eliminated, and when the effective lateral pressure needs to be calculated, the change of the pore water pressure needs to be considered.

It should be noted that since the stainless steel diaphragm 44 is vertically arranged, it can only bear the soil pressure from the horizontal direction, and thus the soil pressure in this embodiment is the horizontal soil pressure.

The device for observing the pressure of the sediment at the bottom of the sea can detect various mechanical states of different loads attached to the sediment in real time under the condition of not being influenced by the depth of the sea water. When in use, the method comprises the following steps:

laying: the submarine sediment pressure observation device is arranged in water, the plug is in an open state at the moment, the pressure in the first channel is equal to hydrostatic pressure, the pressure difference between the first channel and the outside is 0 at the moment, and the detection value of the pressure difference sensor is 0;

penetration: as the cone tip penetrates into the soil body, the pressure difference sensor in the probe detects a pressure value, and the detection value of the pressure difference sensor is the pressure difference at two ends due to the fact that one side of the pressure difference sensor is hydrostatic pressure; when the plug contacts with the soil body, the acting force of the soil body on the plug enables the plug to seal the barrel, and at the moment, the pressure in the first channel does not change any more and is hydrostatic pressure;

and (3) observation: when waves, earthquakes and other loads act, the pressure in the sediment is changed, but the pressure in the first channel is still equal to the hydrostatic pressure, and the detection value of the differential pressure sensor is the pressure value of the load added in the sediment.

The above embodiments have been described only the basic principles and features of the present invention, and the present invention is not limited by the above embodiments, and is not departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (9)

1. A seafloor sediment pressure observation device, comprising:

the probe rod (1) is hollow to form an accommodating cavity (11), and the probe rod (1) comprises a plurality of section rods which are detachably connected;

the conical tip (2) is arranged at one end of the probe rod (1);

the reference pressure barrel (3) is arranged at the other end of the probe rod (1), the reference pressure barrel (3) comprises a barrel body (31), an oil bag (32) located in the barrel body (31) and a plug (33) connected with the barrel body (31) in a sliding mode, and the plug (33) selectively seals the barrel body (31) to enable the oil bag (32) to provide constant pressure;

the probe (4) is arranged at the adjacent joint of the section rods, the probe (4) comprises a shell (41) and a differential pressure sensor (42), a first channel (411) communicated with the inner cavity of the oil bag (32) is arranged in the shell (41), and the differential pressure sensor (42) is used for detecting the differential pressure between the first channel (411) and the outside.

2. The seafloor sediment pressure observation device of claim 1, wherein a mounting hole (412) is formed in the housing (41), the differential pressure sensor (42) is arranged at the mounting hole (412), one end of the mounting hole (412) is communicated with the first channel (411), and the other end of the mounting hole (412) is communicated with the outside.

3. Submarine sediment pressure observing apparatus according to claim 2, wherein a second channel (413) and a pressure guide hole (414) are further provided in the housing (41), the second channel (413) communicating with the accommodating chamber (11) and with the mounting hole (412), the pressure guide hole (414) communicating with the accommodating chamber (11).

4. The device for observing the pressure of seafloor sediments as claimed in claim 1, wherein the pressure difference sensors (42) are two types, namely a pore water pressure sensor and a soil pressure sensor, a permeable stone (43) is arranged at the communication part of the pore water pressure sensor and the outside, and a stainless steel diaphragm (44) is arranged at the communication part of the soil pressure sensor and the outside.

5. Submarine sediment pressure observation device according to claim 1, wherein the cylinder (31) is provided with a first opening and a second opening, the inner cavity of the oil bag (32) is in communication with the first opening, the first opening is in communication with the first channel (411) through a pipeline, and the plug (33) selectively plugs the second opening.

6. The device for observing the pressure of the seabed sediments as claimed in claim 5, wherein the plug (33) comprises a main body part and limiting parts arranged at two ends of the main body part, the main body part is of a reducing structure and is arranged in the second opening in a penetrating manner, and the two limiting parts are respectively positioned at the inner side and the outer side of the barrel body (31).

7. Submarine sediment pressure observation device according to any one of claims 1-6, wherein the end of the stopper (33) is provided with a bottom-touching rod (7), the bottom-touching rod (7) is located outside the cylinder (31), and the bottom-touching rod (7) can push the stopper (33) to block the cylinder (31) under the action of the soil.

8. Seafloor sediment pressure observation device according to any one of claims 1 to 6, further comprising a data acquisition assembly (5), the data acquisition assembly (5) comprising:

a circuit board;

the wire penetrates through the accommodating cavity (11), one end of the wire is connected with the circuit board, and the other end of the wire is connected with the differential pressure sensor (42).

9. The device for observing the pressure of seafloor sediments according to claim 8, further comprising a sealed cabin (6), wherein the sealed cabin (6) is arranged at one end of the probe rod (1) far away from the conical tip (2), and the reference pressure cylinder (3) and the data acquisition assembly (5) are both positioned in the sealed cabin (6).

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