CN220322804U - Intelligent portable deep sediment sampling device - Google Patents
Intelligent portable deep sediment sampling device Download PDFInfo
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- CN220322804U CN220322804U CN202321458531.6U CN202321458531U CN220322804U CN 220322804 U CN220322804 U CN 220322804U CN 202321458531 U CN202321458531 U CN 202321458531U CN 220322804 U CN220322804 U CN 220322804U
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- mud
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- water passing
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- 239000013049 sediment Substances 0.000 title claims abstract description 19
- 238000005070 sampling Methods 0.000 title claims abstract description 15
- 230000000007 visual effect Effects 0.000 claims abstract description 42
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims abstract description 39
- 238000012544 monitoring process Methods 0.000 claims abstract description 15
- 230000000149 penetrating effect Effects 0.000 claims abstract description 10
- WHXSMMKQMYFTQS-UHFFFAOYSA-N Lithium Chemical compound [Li] WHXSMMKQMYFTQS-UHFFFAOYSA-N 0.000 claims description 18
- 229910052744 lithium Inorganic materials 0.000 claims description 18
- 239000004033 plastic Substances 0.000 claims description 13
- 238000004804 winding Methods 0.000 claims description 13
- 239000010802 sludge Substances 0.000 claims description 10
- 239000004677 Nylon Substances 0.000 claims description 5
- 238000000034 method Methods 0.000 claims description 5
- 229920001778 nylon Polymers 0.000 claims description 5
- 230000008054 signal transmission Effects 0.000 claims description 3
- 229920000742 Cotton Polymers 0.000 abstract 2
- 230000007423 decrease Effects 0.000 abstract 1
- 206010063385 Intellectualisation Diseases 0.000 description 2
- 230000009286 beneficial effect Effects 0.000 description 2
- 230000007547 defect Effects 0.000 description 2
- 238000013461 design Methods 0.000 description 2
- 238000010586 diagram Methods 0.000 description 2
- 238000012986 modification Methods 0.000 description 2
- 230000004048 modification Effects 0.000 description 2
- 238000011160 research Methods 0.000 description 2
- 238000006467 substitution reaction Methods 0.000 description 2
- 238000010276 construction Methods 0.000 description 1
- 238000007599 discharging Methods 0.000 description 1
- 239000000428 dust Substances 0.000 description 1
- 230000000694 effects Effects 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 230000002265 prevention Effects 0.000 description 1
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Abstract
The utility model discloses an intelligent portable deep sediment sampling device, which relates to the technical field of water environment monitoring tools, wherein a wide-mouth end at the lower end of an inverted funnel water passing device and the bottom wall of a cylindrical sediment sampler are arranged in a penetrating and open way; the upper end of the inverted funnel water passing device penetrates through the top wall of the cylinder mud taking device, an electromagnetic valve is arranged on a penetrating port, a mud bin is formed between the cylinder mud taking device and the inverted funnel water passing device, and a manual gate is arranged on the side wall of the mud bin; the upper pipe wall of the inverted funnel water passing device is provided with a plurality of mud outlet holes, and each mud outlet hole is connected with a mud outlet baffle plate by a spring. Utilize visual digital display module to combine inside control assembly, control reel rotates, realizes the accurate control to drum mud ware decline degree of depth through high strength conductive cotton rope, and high strength conductive cotton rope is the drum and gets electromagnetic valve of mud ware, turbidity sensor, position finder etc. and transmit the portable control that the electric current made the device, realizes the device intellectuality, reaches the purpose of using manpower sparingly.
Description
Technical Field
The utility model relates to the technical field of water environment monitoring tools, in particular to an intelligent portable deep sediment sampling device.
Background
In the research of the technical fields of water conservancy, hydrology, aquatic products, sea and water environment, under certain conditions, sediment of shallow sea, shoreside and river channels is required to be sampled and analyzed, meanwhile, in some laboratories or research institutions, sediment samples are often required to be collected for experimental analysis, and the existing sampling technology has difficulty. In the prior art, lake sediment is generally obtained through a grab bucket type mud collector, but the vertical distribution of the lake sediment cannot be judged by adopting the grab bucket type mud collector.
Disclosure of Invention
The utility model aims to overcome the defects and shortcomings of the prior art, and provides an intelligent portable deep sediment sampling device which can effectively solve the defects.
In order to achieve the above purpose, the present utility model adopts the following technical scheme: it comprises an upper structure and a lower structure; the upper structure comprises an arched handle, a direct current motor, a lithium battery, an internal control assembly, an access door, a visual digital display module, a winding wheel disc, a hemispherical outer cover and a rope; the semi-spherical outer cover is fixedly provided with an arched handle, the direct current motor, the lithium battery and the internal control component are all fixed inside the semi-spherical outer cover, an access door is arranged in an upper opening of the semi-spherical outer cover, and the visual digital display module is arranged on the outer wall of the semi-spherical outer cover; the lithium battery is respectively and electrically connected with the direct current motor, the internal control assembly, the access door and the visual digital display module; the internal control component is connected with a signal output end of the direct current motor through a wire, and the internal control component is connected with a visual digital display module through a wire; the winding wheel disc is fixed on an output shaft of the direct current motor; the upper end of the rope is fixed on the reel disc, and the lower end of the rope is movably arranged in the bottom wall opening of the hemispherical outer cover in a penetrating manner; the lower structure comprises:
the cylindrical outer cover is of an open structure at the upper end and is fixed on the bottom plate of the hemispherical outer cover;
the cylinder mud taking device is movably arranged in an opening of the bottom plate of the cylindrical outer cover; an inverted funnel water passing device is arranged in the cylindrical sludge taking device, and the wide-mouth end of the lower end of the inverted funnel water passing device and the bottom wall of the cylindrical sludge taking device are arranged in a penetrating and open way; the upper end of the inverted funnel water passing device penetrates through the top wall of the cylinder mud taking device, an electromagnetic valve is arranged on a penetrating port and connected with a visual digital display module through a lead, the electromagnetic valve is fixed with the lower end of a wire rope by utilizing a bracket, and a spiral flow passage is formed in the inner wall of the inverted funnel water passing device; a mud bin is formed between the cylindrical mud taking device and the inverted funnel water passing device, and a manual gate is arranged on the side wall of the mud bin; the upper pipe wall of the inverted funnel water passing device is provided with a plurality of mud outlet holes, each mud outlet hole is connected with a mud outlet baffle plate by a spring, and the other end of the spring is connected with the inner top wall of the cylinder mud taking device;
the one-way exhaust valve is arranged on the top wall of the cylinder mud taking device;
the axial flow pump is arranged in the bottom of the inverted funnel water passing device and is respectively connected with the lithium battery and the internal control component through wires.
Preferably, a turbidity sensor is arranged on the inner wall of the bottom of the inverted funnel water passing device, and the turbidity sensor is respectively connected with a lithium battery and a visual digital display module through wires.
Preferably, the lower edge of the cylinder mud taking device is integrally formed with a wavy bottom support.
Preferably, a position finder is fixed on the upper side of the wall of the cylindrical mud taking device, and the position finder is respectively connected with a lithium battery and a visual digital display module through wires.
Preferably, the cord comprises:
the upper end of the plastic hose is connected with the winding wheel disc, and the lower end of the plastic hose is connected with the cylinder mud taking device;
the central wire is arranged in the plastic hose, the lower end of the central wire is connected with the electromagnetic valve wire, and the upper end of the central wire is connected with the visual digital display module wire;
nylon ropes are arranged and wound outside the plastic hose.
Preferably, a control monitoring component is fixed on the winding wheel disc, a plurality of distance sensors are arranged on the wire rope at intervals, the distance sensors are connected with the control monitoring component in a signal transmission manner, and the control monitoring component is connected with the visual digital display control module through wires.
Preferably, the visual digital display module comprises an internal main board, an external visual electronic display screen, a start key, a plurality of electromagnetic valve control keys, a cord stretching control key, a cord shrinkage control key and an axial flow pump control key; the electronic display screen, the start key, the electromagnetic valve control keys, the cord stretching control key, the cord shrinking control key and the axial flow pump control key are all connected with the main board, and the main board is connected with the internal control assembly through wires.
Preferably, a plurality of sector rubber blades are fixed in the opening of the bottom plate of the cylindrical outer cover.
Preferably, the arch handle is clamped with the hack lever in a movable fit manner, and the hack lever is movably inserted into a hack lever buckle on the side wall of the cylindrical outer cover.
Compared with the prior art, the utility model has the beneficial effects that:
1. the arc handle and the corresponding hack lever are utilized, and through the clamping function, the overall stability of the device during working is improved, and the device is convenient for workers to carry;
2. the visual digital display module is combined with the internal control assembly to control the rotation of the winding wheel disc, the accurate control of the descending depth of the cylindrical mud taking device is realized through the high-strength conductive wire rope, and the high-strength conductive wire rope is used for transmitting current to the electromagnetic valve, the turbidity sensor, the position finder and the like of the cylindrical mud taking device so as to realize the portable control of the device, realize the intellectualization of the device and achieve the aim of saving manpower;
3. the inverted funnel-shaped water passing device in the cylindrical mud taking device can enable the cylindrical mud taking device to sink to the bottom for taking mud;
4. the purpose of collecting at a certain depth can be realized by utilizing the design of the cylinder mud taking device.
Drawings
Fig. 1 is a schematic structural view of the present utility model.
FIG. 2 is a view showing the cylindrical sludge harvester according to the present utility model extending outside the cylindrical housing.
Fig. 3 is a clamping state diagram of the arched handle and the hack lever in the utility model.
Fig. 4 is a schematic view of the structure of the inverted funnel of the present utility model.
Fig. 5 is a schematic view of the bottom structure of the inverted funnel of the present utility model.
Fig. 6 is a schematic view of the structure of the cord of the present utility model.
Fig. 7 is a schematic structural diagram of a visual digital display control module in the present utility model.
FIG. 8 is a schematic view of the construction of the cylinder dredger of the present utility model.
FIG. 9 is a schematic view of the spring and the mud flap of the present utility model.
Fig. 10 is a schematic view of the structure of the one-way exhaust valve in the present utility model.
Fig. 11 is a schematic structural view of the solenoid valve in the present utility model.
Reference numerals illustrate:
the device comprises an arched handle 1, a direct current motor 2, a lithium battery 3, an internal control component 4, an access door 5, a visual digital display module 6, a hack lever 7, a hack lever buckle 8, a coiling wheel disk 9, a hemispherical outer cover 10, a rope 11, a cylindrical mud taking device 12, an electromagnetic valve 13, an inverted funnel water passing device 14, an axial flow pump 15, a cylindrical outer cover 16, an opening 16-1, a start key 17, an electromagnetic valve control key 18, an electronic display screen 19, a rope stretching control key 20, a rope shrinking control key 21, a central conducting wire 22, a plastic hose 23, a nylon rope 24, a manual gate 25, a wavy bottom support 26, a spiral runner 27, a bracket 28, a unidirectional exhaust valve 29, a spring 30, a position finder 31, a turbidity sensor 32, a mud discharging baffle 33 and an axial flow pump control key 34.
Detailed Description
The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings, in which preferred embodiments in the description are given by way of example only, and all other embodiments obtained by those skilled in the art without making any inventive effort are within the scope of protection of the present utility model.
As shown in fig. 1 to 11, the present embodiment adopts the following technical scheme: it comprises an upper structure and a lower structure; the upper structure comprises an arched handle 1, a direct current motor 2, a lithium battery 3, an internal control assembly 4, an access door 5, a visual digital display module 6, a winding wheel disc 9, a hemispherical outer cover 10 and a rope 11; the hemispherical outer cover 10 is fixedly provided with the arched handle 1, the arched handle 1 and the hack lever 7 are clamped in a movable fit manner (through the mutual clamping effect, the whole device can be effectively fixed, instability caused by shaking in the water taking process is prevented, and the hack lever 7 can be retracted into the hack lever buckle 8 after being used up); the direct current motor 2, the lithium battery 3 and the internal control component 4 are all fixed inside the hemispherical outer cover 10, an access door 5 is arranged in an upper opening of the hemispherical outer cover 10, the visual digital display module 6 is arranged on the outer wall of the hemispherical outer cover 10, and the visual digital display module 6 comprises an internal main board, an external visual electronic display screen 19, a starting key 17, a plurality of electromagnetic valve control keys 18, a wire extension control key 20, a wire shrinkage control key 21 and an axial flow pump control key 34; the electronic display screen 19, the start key 17, the electromagnetic valve control keys 18, the rope stretching control key 20, the rope shrinking control key 21 and the axial flow pump control key 34 are all connected with a main board, the main board is connected with the internal control assembly 4 through wires, and the electronic display screen 19 displays whether the telescopic length of the rope 11, the residual electric quantity of the lithium battery 3 and the water level in the cylinder mud taking device 12 are full or not; the lithium battery 3 is respectively and electrically connected with the direct current motor 2, the internal control assembly 4, the access door 5 and the visual digital display module 6; the internal control component 4 is connected with a signal output end of the direct current motor 2 through a lead, so that the wire rope stretching control key 20 and the wire rope shrinking control key 21 are convenient for controlling the retraction and the extension of the wire rope 11, and the internal control component 4 is connected with the visual digital display module 6 through a lead, so that the control of all keys on the visual digital display module 6 is convenient; the reel 9 is fixed on the output shaft of the direct current motor 2; the wire winding wheel disc 9 is fixedly provided with a control monitoring assembly, a plurality of distance sensors are arranged on the wire rope 11 at intervals, the distance sensors are in signal transmission connection with the control monitoring assembly, the control monitoring assembly is connected with a visual digital display control module through wires, the control monitoring assembly identifies the length of the wire rope 11 and transmits the length to the visual digital display module 6, the specific telescopic length is displayed, and the accurate mud taking position is realized while the cylinder mud taking device 12 is stably lifted; the rope 11 comprises a central wire 22, a plastic hose 23 and a nylon rope 24, wherein the upper end of the plastic hose 23 is connected with the reel 9; the central wire 22 is arranged in the plastic hose 23, the lower end of the central wire 22 is connected with the electromagnetic valve 13 through a wire, and the upper end of the central wire 22 is connected with the visual digital display module 6 through a wire; five nylon ropes 24 are arranged, the upper ends of the outer ropes 11 mutually wound on the plastic hose 23 are fixed on the reel 9, and the lower ends of the ropes 11 movably penetrate through the bottom wall opening of the hemispherical outer cover 10;
the lower structure comprises:
a cylindrical outer cover 16, wherein the cylindrical outer cover 16 has an open-top structure and is fixed on the bottom plate of the hemispherical outer cover 10; the hack lever 7 is movably inserted into a hack lever buckle 8 on the side wall of the cylindrical outer cover 16; a step of
The cylindrical mud taking device 12, wherein the cylindrical mud taking device 12 is movably arranged in an opening 16-1 of a bottom plate of a cylindrical outer cover 16, a plurality of fan-shaped rubber blades are fixed in the opening 16-1, and when the cylindrical mud taking device 12 is placed down, the self weight of the cylindrical mud taking device 12 can enable the cylindrical mud taking device 12 to pass through the fan-shaped rubber blades so as to protect the cylindrical mud taking device 12 and play a role in dust prevention; the lower edge of the cylinder mud taking device 12 is integrally formed with a wavy bottom support 26; a position finder 31 is fixed on the upper side of the wall of the cylindrical mud taking device 12, and the position finder 31 is respectively connected with the lithium battery 3 and the visual digital display module 6 through wires; an inverted funnel water passing device 14 is arranged in the cylindrical sludge taking device 12, and the wide-mouth end of the lower end of the inverted funnel water passing device 14 and the bottom wall of the cylindrical sludge taking device 12 are arranged in a penetrating and open way; the upper end of the inverted funnel water passing device 14 penetrates through the top wall of the cylinder mud taking device 12, an electromagnetic valve 13 is arranged on a penetrating port, the electromagnetic valve 13 is connected with a visual digital display module 6 through a wire, the electromagnetic valve 13 is fixed with the lower end of a wire rope 11 through a bracket 28, and a spiral flow passage 27 is formed in the inner wall of the inverted funnel water passing device 14; a mud bin is formed between the cylinder mud taking device 12 and the inverted funnel water passing device 14, and a manual gate 25 is arranged on the side wall of the mud bin and is used for manually opening to obtain a collected mud sample; the upper pipe wall of the inverted funnel water passing device 14 is provided with a plurality of mud outlet holes, each mud outlet hole is connected with a mud outlet baffle 33 by a spring 30, and the other end of the spring 30 is connected with the inner top wall of the cylinder mud taking device 12.
When the device is used, firstly, the hack lever 7 is erected on a pit in the process of collecting mud samples, then the arched handle 1 is clamped on the hack lever 7, and the whole device is hung in the pit in the process of collecting mud samples; then the start key 17 is pressed for a long time, the electronic display screen 19 is lightened to start working, the electromagnetic valve 13 is opened by the electromagnetic valve control key 18, the motor in the axial flow pump 15 is opened by the axial flow pump control key 34, the cord stretching control key 20 is pressed, the direct current motor 2 drives the winding wheel disc 9 to rotate, the cylindrical mud taking device 12 is lowered into water, in the lowering process, the axial flow pump 15 absorbs water and passes through the spiral flow channel 27 in the inverted funnel-shaped device 14, the sinking of the mud taking device 12 is accelerated, the distance sensor on the cord 11 detects the lowering depth in real time, when the required collecting depth is reached, the distance sensor on the cord 11 transmits a signal to the control and monitoring component on the winding wheel disc 9, the control and monitoring component transmits the signal to the visual digital display module 6, the electronic display screen 19 in the visual digital display module 6 displays depth, when the bottom is reached, the turbidity sensor 32 on the inner side of the spiral flow channel 27 judges whether the bottom is reached or not according to the turbidity of the water, and at the same time, the control and monitoring component controls the direct current motor 2 to stop working after the bottom is reached, and the stretching control key 20 is released; the wavy bottom support 26 around the bottom of the cylindrical sludge collector 12 is used for fixing the cylindrical sludge collector 12 and providing a certain space for collecting sludge of the axial flow pump 15; then, the electromagnetic valve 13 is closed by the electromagnetic valve control key 18 to start the mud taking operation, after the mud is sucked by the axial flow pump 15, the internal pressure of the inverted funnel-shaped device 14 is increased, the mud outlet baffle 33 connected with the spring 30 is pushed away, the mud starts to enter the mud bin from the mud outlet hole, when the mud enters the bin body, the pressure in the mud bin is increased, the one-way exhaust valve 29 is automatically opened to exhaust, the position finder 31 transmits a signal back to the visual digital display module 6 through the lead 22 when sensing that the mud bin is full of the mud, and the mud taking operation is finished; the axial flow pump 15 is then turned off and the drum dredge 12 is lifted out of the water using the string control 21, and finally the collected mud is removed from the manual gate 25.
After adopting above-mentioned structure, this embodiment's beneficial effect is as follows:
1. the arc handle and the corresponding hack lever are utilized, and through the clamping function, the overall stability of the device during working is improved, and the device is convenient for workers to carry;
2. the visual digital display module is combined with the internal control assembly to control the rotation of the winding wheel disc, the accurate control of the descending depth of the cylindrical mud taking device is realized through the high-strength conductive wire rope, and the high-strength conductive wire rope is used for transmitting current to the electromagnetic valve, the turbidity sensor, the position finder and the like of the cylindrical mud taking device so as to realize the portable control of the device, realize the intellectualization of the device and achieve the aim of saving manpower;
3. the inverted funnel-shaped water passing device in the cylindrical mud taking device can enable the cylindrical mud taking device to sink to the bottom for taking mud;
4. the purpose of collecting at a certain depth can be realized by utilizing the design of the cylinder mud taking device.
It should be understood that those skilled in the art can make modifications to the technical solutions described in the foregoing embodiments and equivalent substitutions of some technical features, and any modifications, equivalent substitutions, improvements, etc. within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.
Claims (9)
1. An intelligent portable deep sediment sampling device comprises an upper structure and a lower structure; the upper structure comprises an arched handle (1), a direct current motor (2), a lithium battery (3), an internal control assembly (4), an access door (5), a visual digital display module (6), a winding wheel disc (9), a hemispherical outer cover (10) and a rope (11); an arched handle (1) is fixed on the hemispherical outer cover (10), the direct current motor (2), the lithium battery (3) and the internal control component (4) are all fixed inside the hemispherical outer cover (10), an access door (5) is arranged in an upper opening of the hemispherical outer cover (10), and a visual digital display module (6) is arranged on the outer wall of the hemispherical outer cover (10); the lithium battery (3) is respectively and electrically connected with the direct current motor (2), the internal control assembly (4), the access door (5) and the visual digital display module (6); the internal control component (4) is connected with a signal output end of the direct current motor (2) through a wire, and the internal control component (4) is connected with a visual digital display module (6) through a wire; the reel (9) is fixed on the output shaft of the direct current motor (2); the upper end of the rope (11) is fixed on the reel (9), and the lower end of the rope (11) is movably arranged in the bottom wall opening of the hemispherical outer cover (10) in a penetrating way; the method is characterized in that: the lower structure comprises:
the cylindrical outer cover (16) is of an open-ended structure, and is fixed on the bottom plate of the hemispherical outer cover (10);
a cylindrical sludge collector (12), wherein the cylindrical sludge collector (12) is movably arranged in an opening (16-1) of a bottom plate of the cylindrical housing (16); an inverted funnel water passing device (14) is arranged in the cylindrical mud taking device (12), and the wide-mouth end of the lower end of the inverted funnel water passing device (14) and the bottom wall of the cylindrical mud taking device (12) are arranged in a penetrating and open mode; the upper end of the inverted funnel water passing device (14) penetrates through the top wall of the cylinder mud taking device (12), an electromagnetic valve (13) is arranged on a penetrating port, the electromagnetic valve (13) is connected with a visual digital display module (6) through a lead, the electromagnetic valve (13) is fixed with the lower end of a rope (11) through a bracket (28), and a spiral flow passage (27) is formed in the inner wall of the inverted funnel water passing device (14); a mud bin is formed between the cylinder mud taking device (12) and the inverted funnel water passing device (14), and a manual gate (25) is arranged on the side wall of the mud bin; a plurality of mud outlet holes are formed in the pipe wall at the upper end of the inverted funnel water passing device (14), each mud outlet hole is connected with a mud outlet baffle plate (33) by a spring (30), and the other end of the spring (30) is connected with the inner top wall of the cylinder mud taking device (12);
a one-way exhaust valve (29), wherein the one-way exhaust valve (29) is arranged on the top wall of the cylinder mud taking device (12);
the axial flow pump (15) is arranged in the bottom of the inverted funnel water passing device (14), and the axial flow pump (15) is respectively connected with the lithium battery (3) and the internal control assembly (4) through wires.
2. The intelligent portable deep sediment sampling device of claim 1, wherein: the inner wall of the bottom of the inverted funnel water passing device (14) is provided with a turbidity sensor (32), and the turbidity sensor (32) is respectively connected with a lithium battery (3) and a visual digital display module (6) through wires.
3. The intelligent portable deep sediment sampling device of claim 1, wherein: the lower edge of the cylinder mud taking device (12) is integrally formed with a wavy bottom support (26).
4. The intelligent portable deep sediment sampling device of claim 1, wherein: a position finder (31) is fixed on the upper side of the wall of the cylindrical mud taking device (12), and the position finder (31) is respectively connected with a lithium battery (3) and a visual digital display module (6) through wires.
5. The intelligent portable deep sediment sampling device of claim 1, wherein: the cord (11) comprises:
the upper end of the plastic hose (23) is connected with the winding wheel disc (9), and the lower end of the plastic hose (23) is connected with the cylindrical mud taking device (12);
the central wire (22) is arranged in the plastic hose (23), the lower end of the central wire (22) is connected with the electromagnetic valve (13) through a wire, and the upper end of the central wire is connected with the visual digital display module (6) through a wire;
the nylon ropes (24) are arranged in a plurality of ways, and are wound on the outer part of the plastic hose (23).
6. The intelligent portable deep sediment sampling device of claim 1, wherein: the wire winding wheel disc (9) is fixedly provided with a control monitoring assembly, a plurality of distance sensors are arranged on the wire rope (11) at intervals, the distance sensors are connected with the control monitoring assembly in a signal transmission mode, and the control monitoring assembly is connected with a visual digital display control module through a wire.
7. The intelligent portable deep sediment sampling device of claim 1, wherein: the visual digital display module (6) comprises an internal main board, an external visual electronic display screen (19), a start-up key (17), a plurality of electromagnetic valve control keys (18), a wire rope stretching control key (20), a wire rope shrinkage control key (21) and an axial flow pump control key (34); the electronic display screen (19), the start key (17), the electromagnetic valve control keys (18), the wire stretching control key (20), the wire shrinking control key (21) and the axial flow pump control key (34) are all connected with the main board, and the main board is connected with the internal control assembly (4) through wires.
8. The intelligent portable deep sediment sampling device of claim 1, wherein: a plurality of sector rubber blades are fixed in an opening (16-1) of the bottom plate of the cylindrical outer cover (16).
9. The intelligent portable deep sediment sampling device of claim 1, wherein: the arched handle (1) is clamped with the hack lever (7) in a movable fit manner, and the hack lever (7) is movably inserted into the hack lever buckle (8) on the side wall of the cylindrical outer cover (16).
Priority Applications (1)
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CN202321458531.6U CN220322804U (en) | 2023-06-08 | 2023-06-08 | Intelligent portable deep sediment sampling device |
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CN202321458531.6U CN220322804U (en) | 2023-06-08 | 2023-06-08 | Intelligent portable deep sediment sampling device |
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CN220322804U true CN220322804U (en) | 2024-01-09 |
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CN202321458531.6U Active CN220322804U (en) | 2023-06-08 | 2023-06-08 | Intelligent portable deep sediment sampling device |
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