CN114878252A

CN114878252A - Atmospheric settlement collection device for geological survey

Info

Publication number: CN114878252A
Application number: CN202210135788.1A
Authority: CN
Inventors: 赵兴琦; 沙晴; 郭�中
Original assignee: First Geological Brigade of Shandong Provincial Bureau of Geology and Mineral Resources of First Geological and Mineral Exploration Institute of Shandong Province
Current assignee: First Geological Brigade of Shandong Provincial Bureau of Geology and Mineral Resources of First Geological and Mineral Exploration Institute of Shandong Province
Priority date: 2022-02-15
Filing date: 2022-02-15
Publication date: 2022-08-09

Abstract

The invention discloses an atmospheric sedimentation collecting device for geological survey, which comprises: a liquid storage tank; accept the subassembly, it including folding skeleton and set up in toughness tarpaulin on the folding skeleton, folding skeleton expandes so that toughness tarpaulin is and leaks hopper-shaped expansion, the liquid storage pot install in accept on the subassembly and be linked together with toughness tarpaulin's discharge gate. According to the atmospheric settlement collecting device for geological investigation, the tough waterproof cloth is funnel-shaped through unfolding of the folding framework, the liquid storage tank is fixed through the bearing assembly and is located below the discharge hole of the tough waterproof cloth, rainwater borne by the tough waterproof cloth is drained into the liquid storage tank, so that the effect of the liquid storage tank on collecting accumulated water is guaranteed, and the accuracy of detection data is improved.

Description

Atmospheric settlement collection device for geological survey

Technical Field

The invention relates to production of an atmospheric settlement collecting device, in particular to an atmospheric settlement collecting device for geological survey.

Background

The investigation of atmospheric precipitation collection can be performed in a manner that provides visual observation by collecting rainwater during rainfall, then allowing the collected rainwater to stand until the dust in the rainwater forms a precipitate, and condensing the dust at the bottom of the container, and by measuring the volume of the collected liquid and the thickness of the precipitate, the dust content in the atmosphere can be roughly estimated.

According to patent No. cn202120417326.x, publication (publication) day: 2021-04-02, discloses an atmosphere settlement collecting device for geological survey, which comprises a main box body, the upper portion of the main box body is provided with a flip box body, the upper portion of the flip box body is connected with two turning plates through a rotating shaft, the turning plates are provided with rain sensors, the lower portions of the turning plates are fixedly connected with a buzzer, the lower portion of the flip box body is provided with a collecting tank, the lower left side of the collecting tank is connected with an inclined plate, the right side of the main box body is provided with a particulate matter collecting box body, the upper portion of the particulate matter collecting box body is provided with a brush roller, the lower portion of the particulate matter collecting box body is connected with a particulate matter discharge pipe, and the lower portion of the main box body is provided with a rain water collecting box body. The upper portion of the main tank body is equipped with the flip box, the upper portion of flip box is connected with two through the pivot and turns over the board, can open and close when needing, collect and do the rate of subsiding, the right side of main tank body is equipped with the particulate matter and collects the box, the aperture has evenly been seted up on the upper portion of particulate matter collection box, a particulate matter gets into the inside of particulate matter collection box, and brush particulate matter down through a brush roller section of thick bamboo, get into the particulate matter discharge pipe, turn over and be equipped with rain sensor on the board, can open bee calling organ sound when raining, the lower part of rain collection box is equipped with the rainwater collecting pipe, a data is subsided to the collection humidity.

The device is simple, namely a barrel structure is adopted, then the barrel is fixed on the support, and the barrel is lifted to a preset height through the support, so that rainwater is collected. The aperture of the port of the barrel body is limited, so that the effect of collecting rainwater by the barrel body is general.

Disclosure of Invention

The invention aims to provide an atmospheric sedimentation collecting device for geological survey, which is used for solving the problems.

In order to achieve the above purpose, the invention provides the following technical scheme: an atmospheric sedimentation collection device for geological survey, comprising:

a liquid storage tank;

accept the subassembly, it including folding skeleton and set up in toughness tarpaulin on the folding skeleton, folding skeleton expandes so that toughness tarpaulin is and leaks hopper-shaped expansion, the liquid storage pot install in accept on the subassembly and be linked together with toughness tarpaulin's discharge gate.

Preferably, the folding skeleton comprises a plurality of main bone rods and a plurality of bone-attached rods, and one ends of the bone-attached rods are slidably arranged on the main bone rods; the supporting assembly further comprises a connecting seat, one ends of the main bone rods and one ends of the auxiliary bone rods are rotatably arranged on the connecting seat, and the auxiliary bone rods are driven to enable the folding framework to keep or release unfolding.

Preferably, the main framework rod is provided with a guide eave and a limiting part which are distributed oppositely, the limiting part is provided with a detention groove towards the outer wall of one side of the guide eave, and the guide eave enables the end part of the auxiliary framework rod to stay in the detention groove to enable the folding framework to be unfolded or guides out the detention groove to enable the folding framework to be folded.

Preferably, a torsion spring is arranged at the joint of the bone-attaching rod and the connecting seat, and the torsion spring is used for furling the folding framework which is released from unfolding.

Preferably, a vibration component is arranged between every two main rods and used for driving the flexible waterproof cloth to shake according to a preset frequency.

Preferably, the vibration assembly comprises a sealing plate, an elastic connecting fin is arranged on the sealing plate, the elastic connecting fin is used for sealing a space between the sealing plate and the flexible waterproof cloth, and a whistle block is arranged on the sealing plate.

Preferably, a plurality of metal sheets are arranged in the elastic connecting web, a preset distance is kept between the metal sheets and the sealing plate, and the metal sheets are vibrated by the sound of the whistle block.

Preferably, a plurality of wind blades are stamped on the metal sheet, the wind blades are vibrated by the sound produced by the wind whistle blocks, and the metal sheet is transmitted by the wind blades to vibrate together.

Preferably, an elastic cloth is arranged between every two bone attaching rods, the elastic cloth is connected to the sealing plate and forms a wind scoop with a conical structure, and a wind whistle block is installed at an air outlet of the wind scoop.

Preferably, a plurality of the wind scoops are provided with mutually communicated ventilation holes.

In the technical scheme, the atmospheric sedimentation collecting device for geological survey provided by the invention has the following beneficial effects: expansion through folding skeleton makes toughness tarpaulin be and leaks hopper-shaped, and the liquid storage pot is then fixed through accepting the subassembly to be located toughness tarpaulin's discharge gate below, and the rainwater that toughness tarpaulin was accepted can the drainage to the liquid storage pot in, thereby guarantees the collection effect of its liquid storage pot to ponding. And the adopted tough waterproof cloth is made of a non-hydrophilic material, so that rainwater can form water drops to slide into the liquid storage tank, the liquid is prevented from contacting the tough waterproof cloth to form water flow, and dust in the water flow is remained on the tough waterproof cloth, so that the detection data is influenced.

Drawings

In order to more clearly illustrate the embodiments of the present application or technical solutions in the prior art, the drawings required in the embodiments will be briefly described below, it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to these drawings.

FIG. 1 is a schematic diagram of an overall structure provided in an embodiment of the present invention;

FIG. 2 is a schematic diagram of an explosive structure provided by an embodiment of the present invention;

FIG. 3 is a schematic view of a portion of a folding frame according to an embodiment of the present invention;

FIG. 4 is a partially enlarged structural view of a main rod according to an embodiment of the present invention;

fig. 5 is a schematic structural view of the folding frame according to the embodiment of the present invention in a folded state;

fig. 6 is a schematic sectional view of the elastic connecting web according to the embodiment of the present invention

Fig. 7 is a schematic structural diagram of a first implementation of a wind blade according to an embodiment of the present invention;

fig. 8 is a schematic structural diagram of a second embodiment of a wind blade according to an embodiment of the present invention;

fig. 9 is a schematic structural diagram of a third implementation manner of the wind blade according to the embodiment of the present invention.

Description of reference numerals:

1. a liquid storage tank; 2. a receiving assembly; 21. a connecting seat; 22. a conical guide ledge; 3. folding the framework; 31. A main bone rod; 311. a guide chute; 312. a first guide groove; 313. a second guide groove; 314. a guide eave; 315. a limiting part; 32. a bone-attached rod; 321. a guide roller; 4. a tough tarpaulin; 41. a wind scoop; 411. a vent hole; 5. a whistle block; 6. elastic connecting webs; 61. closing the plate; 8. a metal foil; 81. and (4) wind sheets.

Detailed Description

In order to make the technical solutions of the present invention better understood, those skilled in the art will now describe the present invention in further detail with reference to the accompanying drawings.

As shown in fig. 1 to 9, an atmospheric sedimentation collecting apparatus for geological survey comprises:

a liquid storage tank 1;

accept subassembly 2, it includes folding skeleton 3 and sets up toughness tarpaulin 4 on folding skeleton 3, and folding skeleton 3 expandes so that toughness tarpaulin 4 is the expansion of leaking hopper-shaped, and liquid storage pot 1 is installed and is linked together on accepting subassembly 2 and with toughness tarpaulin 4's discharge gate.

Specifically, the liquid storage tank 1 in the above technical solution is specifically a transparent plastic cylinder, and the outer wall thereof is provided with scale marks for observing the height of the liquid in the liquid storage tank 1 and the height of the precipitate. Further, in the embodiment, the flexible waterproof cloth 4 is fixed on the inner side of the folding frame 3, and the folding frame 3 refers to the umbrella rib structure, except that after the umbrella rib structure in the above embodiment is unfolded, the whole receiving assembly 2 is in a funnel shape.

Among the above-mentioned technical scheme, the expansion through folding skeleton 3 makes toughness tarpaulin 4 be and leaks hopper-shaped, and liquid storage pot 1 is then fixed through accepting subassembly 2 to be located toughness tarpaulin 4's discharge gate below, and the rainwater that toughness tarpaulin 4 accepted can be drained to liquid storage pot 1 in, thereby guarantees the collection effect of its liquid storage pot 1 to ponding. And the adopted tough waterproof cloth 4 is made of a non-hydrophilic material, so that rainwater can form water drops and slide into the liquid storage tank 1, the liquid is prevented from contacting the tough waterproof cloth 4 to form water flow, and dust in the water flow is remained on the tough waterproof cloth 4, so that the detected data is influenced.

As a further embodiment of the present invention, the folding skeleton 3 comprises a plurality of main rods 31 and a plurality of bone-attached rods 32, one end of each bone-attached rod 32 is slidably disposed on the main rod 31; the receiving assembly 2 further comprises a connecting seat 21, one ends of the main bone rods 31 and the auxiliary bone rods 32 are rotatably arranged on the connecting seat 21, and the auxiliary bone rods 32 are driven to keep or release the folding framework 3. Specifically, the liquid storage tank 1 is screwed in the threaded port at the bottom of the connecting seat 21. The tough waterproof cloth 4 is installed on the side walls of the main bone rods 31, the side walls of the connecting seat 21 in the embodiment are provided with a plurality of grooves, the ports at the two ends of each groove are respectively provided with a rotating shaft, the main bone rods 31 and the auxiliary bone rods 32 in the technical scheme are both rotatably installed on the rotating shafts, the auxiliary bone rods 32 are distributed near the liquid storage tank 1 according to the figure 3, and the main bone rods 31 are distributed at one side far away from the liquid storage tank 1. When the folding framework 3 is unfolded, the main bone rods 31 of any number are pushed and simultaneously move downwards along the axial direction of the liquid storage tank 1, the auxiliary bone rods 32 are positioned on the main bone rods 31 and slide towards one end far away from the connecting seat 21, and after a preset distance, the locking mechanism is triggered and locked in a 'funnel-shaped' state when being unfolded.

Further, the locking mechanism mentioned in the embodiments may be a pressing type rebounding self-locking member installed in the groove, and a hook is hooked at the end of the bone-attached rod 32, and after rotating to a predetermined angle, the hook pushes the pressing type rebounding self-locking member, thereby achieving locking; or the bone-attached rod 32 is provided with an elastic clamping piece, and after the bone-attached rod 32 slides to a preset distance along the main bone rod 31, the elastic clamping piece is clamped in a groove formed in the side wall of the main bone rod 31, so that locking is realized; or a locking mechanism known to those skilled in the art.

It should be noted that the main bone rods 31 and the auxiliary bone rods 32 in the above embodiments have a minimum of six, and a maximum of 14.

Moreover, be provided with toper guide eaves 22 (scribble and not having hydrophilic coating, prior art does not make public) on connecting seat 21, toper guide eaves 22 is used for accepting the drop of toughness tarpaulin 4 whereabouts to guarantee that it falls to liquid storage pot 1 between two parties, avoid the liquid of whereabouts to flow along the inner wall, produce at connecting seat 21 and liquid storage pot 1 seam department and detain.

As a preferred embodiment of the present invention, the main rod 31 is provided with a guiding brim 314 and a limiting portion 315 which are distributed oppositely, the outer wall of the limiting portion 315 facing to the guiding brim 314 is provided with a detention groove, the guiding brim 314 makes the end of the auxiliary rod 32 stay in the detention groove to unfold the folding frame 3, or guides the detention groove to fold the folding frame 3. Specifically, as shown in fig. 3, the main rod 31 is a concave structure, the inner walls of the two sides of the groove are both provided with guide slots 311, and the side walls of the two sides of the auxiliary rod 32 are both provided with guide rollers 321. Further, the end of the bone-attaching rod 32 is located in the groove, and the sliding roller 321 is slidably disposed in the sliding guide slot 311. In the embodiment, the guiding ledge 314 and the limiting portion 315 are both located at an end of the guiding chute 311 near one end of the connecting seat 21, the limiting portion 315 is centrally located in the guiding chute 311, and the limiting portion 315 and an inner wall of one side of the guiding chute 311 form a first guiding slot 312 and an inner wall of the other side of the guiding chute 311 form a second guiding slot 313. In a specific implementation process, the main rod 31 is forced to rotate, the auxiliary rod 32 slides along the guide chute 311 to move towards the connection seat 21, the guide roller 321 enters the first guide groove 312 from the guide chute 311, then along the top end of the first guide groove 312, and then is tangent to the side wall of the guide eave 314, and the guide eave 314 slides into the retention groove on the limiting portion 315 under the guidance of the guide eave 314. Throughout the sliding process, the user will clearly feel the sign that the collapsed framework 3 will collapse after it has been deployed to its extreme. At this time, the user releases the hand, and the slide guide roller 321 is retained in the retention groove of the stopper 315. Because the torsion spring is arranged at the joint of the bone-attached rod 32 and the connecting seat 21, under the action of the torsion spring, the bone-attached rod 32 generates an upward lifting force, and the stay groove just hangs the guide sliding roller 321 in the stay groove.

Further, when the folding is needed (when fig. 1 is switched to fig. 4), the main rod 31 is pressed again, the sliding guide roller 321 slides along the retention groove, and in the process, the sliding guide roller is tangent to the outer wall of the other side of the guide eaves 314, so that the guide eaves 314 retreats from the retention groove and slides into the second guide groove 313, and slides into the other end of the guide groove 311 under the action of the torsion spring.

Because above-mentioned technical scheme has adopted the inner wall that the funnel was made to hydrophilic material not, this makes the rainwater fall to toughness tarpaulin 4 in the time, the rainwater can condense to the drop, then slide down along toughness tarpaulin 4's surface, because above-mentioned material is not hydrophilic material, consequently when the position that the drop of condensation is in toughness tarpaulin 4 surface can't be because of self gravity gliding, then can stop toughness tarpaulin 4, this must take place, when the drop of water is air-dried or is evaporated, the dust in that drop of water will condense in this department.

As an embodiment of the present invention to solve the above problem, a vibration assembly is provided between each two main rods 31, and the vibration assembly is used to drive the flexible tarpaulin 4 to vibrate at a predetermined frequency. Specifically, the vibration component in the above technical scheme can be a vibration motor, and the flexible waterproof cloth 4 is vibrated; or the motor or the electric telescopic rod drives the connecting rod structure to swing, so as to knock the tough waterproof cloth 4; or a vibration mechanism known to those skilled in the art. Through carrying out the shake of low frequency to toughness tarpaulin 4, the mode that utilizes the shake can be solved the drop of water and detained the problem emergence on the surface completely.

As a further embodiment of the present invention, the vibration assembly comprises a closing plate 61, the closing plate 61 being provided with elastic connecting fins 6, the elastic connecting fins 6 serving to seal a space between the closing plate 61 and the flexible tarpaulin 4, and the closing plate 61 being provided with whistle blocks 5. Specifically, in the above embodiment, the size of the sealing plate 61 is equal to the state shown in fig. 4, and the distance between the two main bone rods 31 is equal to the preset distance, in the embodiment, the sealing plate 61 is connected to the flexible waterproof cloth 4 and the adjacent side walls of the two main bone rods 31 through the elastic connecting webs 6, and the width of the side walls of the main bone rods 31 is equal to the preset distance between the sealing plate 61 and the sealing plate 61. Further, the air outlet is provided on the sealing plate 61 in the embodiment, the wind whistle block 5 is installed at the air inlet of the sealing plate 61, when wind passes through the wind whistle block 5, the wind whistle block 5 can generate whistle sound, and in the relative sealed space, the internal air is vibrated by the whistle sound, so that the flexible waterproof cloth 4 in a tight state (in an unfolded state, fig. 1) can resonate to a certain degree.

As a further embodiment of the present invention, a plurality of metal sheets 8 are provided in the elastic connecting web 6, the plurality of metal sheets 8 are spaced apart from the sealing plate 61 by a predetermined distance and also spaced apart from the flexible tarpaulin 4 by a predetermined distance, and the distance between the metal sheets 8 and the flexible tarpaulin 4 is smaller than the distance between the metal sheets and the sealing plate 61 (detailed data is not expanded in detail), and the metal sheets 8 are vibrated by the sound of the whistle 5. Specifically, in the above embodiment, the plurality of metal sheets 8 are distributed in a linear array, and the spacing between each metal sheet 8 is kept within a predetermined range (detailed data is not disclosed). In a specific implementation, when the folding frame 3 is switched from the state shown in fig. 1 to the state shown in fig. 4, the side walls of the plurality of metal sheets 8 contact each other, and are combined to conform to the specification of the sealing plate 61. When wind passes through the wind whistle block 5, the wind whistle block 5 can generate whistle sound, the internal air is vibrated by the whistle sound in the relative sealed space, and the plurality of metal sheets 8 are vibrated by the vibration of the air, so that the vibration frequency is amplified, the tough waterproof cloth 4 in a tight state is vibrated by the influence of the vibration, and water drops condensed on the tough waterproof cloth 4 are vibrated and slide down.

As a further preferred embodiment of the present invention, as shown in fig. 5, a plurality of wind flaps 81 are stamped on the metal sheet 8, the wind flaps 81 vibrate due to the sound of the wind whistle 5, and the metal sheet 8 vibrates due to the transmission of the wind flaps 81. Specifically, a plurality of wind blades 81 are stamped on each metal sheet 8 in the above embodiments, and the included angle between the metal sheet 8 and the wind blades 81 is kept at an obtuse angle (data is not expanded). When the folding frame 3 is switched from the state shown in fig. 1 to the state shown in fig. 4, the side walls of the plurality of metal sheets 8 contact with each other, and are combined to conform to the specification of the sealing plate 61. When wind passes through the wind whistle block 5, the wind whistle block 5 can generate whistle sound, the inside air is vibrated due to the whistle sound in the opposite sealed space, the end part of the wind sheet 81 is vibrated due to the vibration, the vibration is transmitted to the whole metal sheet 8 through the wind sheet 81, the vibration is further amplified by utilizing the metal sheet 8, so that the tough waterproof cloth 4 in a tight state is vibrated due to the influence of the vibration, and water drops condensed on the tough waterproof cloth 4 can slide downwards due to the vibration.

The wind blades 81 in the above embodiment are of a special-shaped structure, because the wind blades 81 with smaller volume are more prone to flutter together due to the vibration of air.

As a first embodiment of the wind blade 81 provided by the present invention, as shown in fig. 5, the wind blade 81 is formed by punching, and may have any shape that can be directly obtained by simple punching, which is well known to those skilled in the art, such as a diamond shape, a rectangular shape, a triangular shape, a circular shape, and an oval shape.

As a second embodiment of the wind blade 81 provided by the present invention, as shown in fig. 6, the wind blade 81 is formed in a rectangular shape by punching, and the rectangular shape is formed with a multi-end bent portion by bending, and is specifically divided into a first bent portion connected to the metal thin plate 8, a bent direction of which is downward, and a second bent portion connected to the first bent portion, which is in an arc shape as a whole, and an end portion of which is upward. Further, as can be seen from fig. 6, the central axis of the wind vane 81 is punched to form a V-shaped cross section, and compared with a simple punching shape, the cross section of the wind vane 81 has a larger contact surface with air and a longer overall length, and the end of the second bending portion returns to the punching hole of the wind vane 81 again, and the side wall of the second bending portion keeps a predetermined distance from the inner wall of the punching hole, so that the structure vibrates through air, and the vibration frequency is higher along with the vibration, and during the vibration process, the end of the second bending portion can knock the metal sheet 8, so that the metal sheet 8 obtains a higher vibration rate, thereby further enhancing the vibration, and the vibration frequency of the tough tarpaulin 4 is more obvious.

As a third embodiment of the wind plate 81 provided by the present invention, as shown in fig. 7, the wind plate 81 is punched into a rectangular structure, and then is twisted into a long thread shape and is disposed obliquely, compared with a simple punched shape, the multi-curved structure has a larger contact surface with air and a longer overall length, and the end of the second bending portion returns to the punched hole of the wind plate 81 again, and the side wall of the second bending portion keeps a predetermined distance from the inner wall of the punched hole, and the structure vibrates with the vibration through the air vibration, so that the vibration frequency of the metal sheet 8 is higher, and the vibration is further enhanced, and the vibration frequency of the flexible tarpaulin 4 is more obvious.

As a fourth embodiment of the wind blade 81 provided by the present invention, as shown in fig. 8, the wind blade 81 is punched into a rectangular structure, and then bent into a round bar structure, and the end of the round bar structure is spot welded with a tapered threaded coil 82, the cross section of the tapered threaded coil 82 is a rectangular structure, the frequency of vibration is higher along with the vibration by air vibration, and in the vibration process, the tapered threaded coils 82 vibrate with each other, the vibration force is amplified on the tapered threaded coils 82, then the wind blade 81 with a hollow round bar structure vibrates, and finally the wind blade is transmitted to the metal sheet 8, and the vibration is amplified by the metal sheet 8, thereby further enhancing the vibration, and making the vibration frequency of the flexible waterproof cloth 4 more obvious.

In the technical scheme, the flexible waterproof cloth 4 can sound through wind passing through the wind whistle block 5 to trigger the vibration component to vibrate the flexible waterproof cloth 4, but the direction of the nature is not fixed, so that how to ensure that the wind generated in any direction can still excite all the vibration components at the same time,

as an embodiment of the present invention to solve the above problems, as shown in fig. 1 and 5, an elastic cloth is disposed between each two bone-attaching rods 32, the elastic cloth is connected to the sealing plate 61 to form a wind scoop 41 with a tapered structure, and a wind whistle 5 is installed at the wind outlet of the wind scoop 41. Specifically, when the main rod 31 is forced to rotate, and the auxiliary rod 32 slides along the guide slot 311 and moves toward the connecting seat 21, the guide roller 321 enters the first guide slot 312 through the guide slot 311, then along the top end of the first guide slot 312, and then is tangent to the side wall of the guide ledge 314, and slides down into the retention slot on the limiting portion 315 under the guidance of the guide ledge 314. Throughout the sliding process, the user will clearly feel the sign that the collapsed framework 3 will collapse after it has been deployed to its extreme. At this time, the user releases the hand, and the slide guide roller 321 is retained in the retention groove of the stopper 315. Because the torsion spring is arranged at the joint of the bone-attached rod 32 and the connecting seat 21, under the action of the torsion spring, the bone-attached rod 32 generates upward raising force, and the stay groove just hangs the guide sliding roller 321 in the groove. So that the device is unfolded to be in the state of figure 1, the main bone rod 31 and the auxiliary bone rod 32 are in a triangular structure at the moment, the wind scoop 41 is unfolded to be in a trapezoidal structure at the moment, and the structure has good wind collecting effect, thereby ensuring that the generated airflow is enough to make the wind whistle 5 generate sound.

Further, as can be seen from fig. 6, in the embodiment, the plurality of wind scoops 41 are all provided with ventilation holes 411 that are communicated with each other. Specifically, the ventilation holes 411 in the embodiment are located at two waists of the trapezoid structure and distributed close to the whistle blocks 5, when one side is windy, wind gushes into the wind scoop 41, and the airflow flowing through the ventilation holes 411 enables the whistle blocks 5 to sound simultaneously.

Note that the whistle piece 5 is provided obliquely, and the whistle is inclined to exit toward the one vent hole 411.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the invention.

Claims

1. An atmospheric sedimentation collection device for geological survey, comprising:

a liquid storage tank (1);

accept subassembly (2), it including folding skeleton (3) and set up in toughness tarpaulin (4) on folding skeleton (3), folding skeleton (3) expand so that toughness tarpaulin (4) are the expansion of leaking hopper-shaped, liquid storage pot (1) install in accept on subassembly (2) and be linked together with the discharge gate of toughness tarpaulin (4).

2. An atmospheric sedimentation collection device for geological survey according to claim 1, wherein the folding skeleton (3) comprises a plurality of main bars (31) and a plurality of attached bars (32), one end of the attached bars (32) is slidably arranged on the main bars (31); the bearing component (2) further comprises a connecting seat (21), one end of each of the main bone rods (31) and the auxiliary bone rods (32) is rotatably arranged on the connecting seat (21), and the auxiliary bone rods (32) are driven to keep or release the folding framework (3).

3. The atmospheric sedimentation collection device for geological survey according to claim 2, wherein the main framework rod (31) is provided with a guide eaves (314) and a limiting part (315) which are distributed oppositely, the outer wall of the limiting part (315) facing one side of the guide eaves (314) is provided with a detention groove, the guide eaves (314) enable the end part of the auxiliary framework rod (32) to stay in the detention groove to enable the folding framework (3) to be unfolded, or the detention groove is led out to enable the folding framework (3) to be folded.

4. The atmospheric sedimentation collection device for geological survey as claimed in claim 3, wherein a torsion spring is provided at the connection of the bone-attaching rod (32) and the connection seat (21), and the torsion spring is used for folding the folding skeleton (3) which is released from unfolding.

5. An atmospheric sedimentation collection device for geological survey according to claim 2, characterized in that a vibration component is arranged between each two main rods (31), and the vibration component is used for driving the flexible tarpaulin (4) to shake according to a predetermined frequency.

6. An atmospheric sedimentation collection device for geological survey according to claim 5, characterized in that the vibration assembly comprises a closing plate (61), the closing plate (61) is provided with an elastic connection fin (6), the elastic connection fin (6) is used for sealing a space between the closing plate (61) and the flexible tarpaulin (4), and the closing plate (61) is provided with a whistle block (5).

7. An atmospheric sedimentation trap apparatus for geological survey according to claim 6, wherein a plurality of metal thin plates (8) are provided in the elastic connecting web (6), a plurality of metal thin plates (8) are kept at a predetermined interval from the sealing plate (61), and the metal thin plates (8) are vibrated by the sound of the whistle piece (5).

8. The atmospheric sedimentation collection device for geological survey according to claim 7, wherein a plurality of wind pieces (81) are stamped on the metal sheet (8), the wind pieces (81) are vibrated by the sound generated by the wind whistle blocks (5), and the metal sheet (8) is transmitted by the wind pieces (81) to vibrate together.

9. The atmospheric sedimentation collection device for geological survey according to claim 2, wherein an elastic cloth is arranged between every two of the bone-attached rods (32), the elastic cloth is connected to the closing plate (61) and forms a wind scoop (41) with a conical structure, and a wind whistle block (5) is arranged at the wind outlet of the wind scoop (41).

10. The atmospheric sedimentation collection device for geological survey according to claim 9, wherein a plurality of the wind scoops (41) are provided with mutually communicated vent holes (411).