CN211553961U - Air-dropping prevention multi-parameter monitoring and water collecting device for water dropping of karst cave - Google Patents

Abstract

The utility model discloses a karst cave is dripped anticreep gas multi-parameter monitoring and water-collecting device, including plasticity funnel, the adjustable telescopic link of funnel, anticreep gas evaporation monitoring barrel and monitoring devices and adjustable universal foot rest, plasticity funnel is connected with the one end of the adjustable telescopic link of funnel, and the other end of the adjustable telescopic link of funnel is connected with the upper end of anticreep gas evaporation monitoring barrel, and the adjustable telescopic link of funnel is cavity form and communicates the inside of plasticity funnel and anticreep gas evaporation monitoring barrel, and monitoring devices is fixed in the downside of anticreep gas evaporation monitoring barrel, and adjustable universal foot rest is fixed in monitoring devices's downside. The utility model overcomes the degasification problem that produces when a plurality of monitoring such as the collection of dripping and drip rate, the high efficiency is applicable to the many indexes monitoring and the water sample collection of arbitrary high drip point for a long time, realizes real-time high accuracy measurement, and easy and simple to handle, high-efficient practical provides better experimental data basis for the carbon cycle characteristic of karst key area and the research of migration mechanism.

Description

Air-dropping prevention multi-parameter monitoring and water collecting device for water dropping of karst cave

Technical Field

The utility model relates to a cave monitoring field, in particular to anticreep gas multiparameter monitoring and water-collecting device that karst cave was dripped.

Background

Along with the intensive karst research, cave drip water collection methods are continuously innovated, the collected cave drip water is greatly improved on an automatic monitoring method, but the influence of the degassing effect of the drip water on the drip water chemical property is not noticed while various indexes are achieved by utilizing the drip water for high efficiency.

In the general research on the carbon circulation mechanism, the collection and monitoring of cave water drops are mainly used for researching the carbon circulation and migration mechanism of atmospheric precipitation passing through a soil layer and an aeration zone in a surface layer karst key zone, so that the indication significance of the cave water drops on the deposition environment of secondary sediments in a cave and the external climate environment is further discussed, the precision requirements on various physicochemical properties and isotope indexes in the water drops are high, the migration rule and the circulation characteristic in the surface layer karst key zone are further calculated through the physicochemical property indexes, and the current collection method still can cause the following problems:

(1) when water drops flow out of a karst pipe of bedrock, due to the fact that water drops enter a cave air environment and are influenced by the air pressure in the air and the air pressure difference in a karst pipeline, CO2 in the air is far smaller than that in the karst pipeline, a degassing effect caused by the fact that liquid phase CO2 molecules free in the water drops escape from the water drops can be generated, the partial pressure difference of water, gas and carbon dioxide in a measurement result is an aggressive state in a negative value, and SI is larger than zero, a contradiction phenomenon of a deposition state is generated, and great inconvenience is brought to research on the migration condition of CO2 in a key zone of surface karst.

(2) The traditional dripping and dripping amount recording method comprises the following steps; the detection of the water dripping flow is usually a single detection index, and when physical and chemical property indexes of the water dripping and water sample collection are carried out simultaneously, the problem of errors caused by property change of the water dripping in the detection process of multiple indexes is inevitably solved, so that the research on carbon cycle of the water dripping in the cave is even influenced to a certain extent.

Disclosure of Invention

An object of the utility model is to provide a anticreep gas multiparameter monitoring and water-collecting device that karst cave dripped solves one of above-mentioned technical problem at least.

According to the utility model discloses an aspect provides anticreep gas multi-parameter monitoring and water-collecting device that karst cave dripped, including plasticity funnel, the adjustable telescopic link of funnel, anticreep gas evaporation monitoring barrel and monitoring devices and adjustable universal foot rest, the plasticity funnel is connected with the one end of the adjustable telescopic link of funnel, the other end of the adjustable telescopic link of funnel is connected with the upper end of anticreep gas evaporation monitoring barrel, the adjustable telescopic link of funnel is cavity form and communicates the inside of plasticity funnel and anticreep gas evaporation monitoring barrel, monitoring devices is fixed in the downside of anticreep gas evaporation monitoring barrel, adjustable universal foot rest is fixed in monitoring devices's downside.

In some embodiments, the anti-outgassing evaporation monitoring barrel comprises a light-tight barrel body, a barrel cover, a water sample collection glass tank, an anti-dripping water inlet pipe and a floating plate, wherein the water sample collection glass tank, the anti-dripping water inlet pipe and the floating plate are all located in the light-tight barrel body, the barrel cover is fixed at the upper end of the light-tight barrel body and seals the light-tight barrel body, the water sample collection glass tank is fixed at the bottom of the light-tight barrel body, one end of the anti-dripping water inlet pipe is connected with an adjustable telescopic rod of a funnel, the other end of the anti-dripping water inlet pipe extends into the lower end of the water sample collection glass tank, the upper end of the anti-dripping water inlet pipe is opened, the floating plate is.

In some embodiments, the anti-outgassing evaporation monitoring barrel further comprises a water pumping pipe and a water pumping device interface, the water pumping device interface is fixed outside the barrel cover, one end of the water pumping pipe penetrates through the floating plate and extends into the water sample collection glass tank, and the other end of the water pumping pipe is connected with the water pumping device interface.

In some embodiments, anticreep gas evaporation monitoring bucket still includes fixture block and fixture block under the kickboard on the kickboard, fixture block and kickboard down all are fixed in the antidrip and spatter outside the inlet tube on the kickboard, fixture block is located the top of fixture block under the kickboard and is located the top of water sample collection glass jar on the kickboard, the kickboard is located fixture block and kickboard down between the fixture block.

In some embodiments, the anti-outgassing evaporation monitoring barrel further comprises a U-shaped drain pipe, the U-shaped drain pipe is fixed to one side of the bottom of the light-tight barrel body, and one end of the U-shaped drain pipe is communicated with the inside of the light-tight barrel body.

In some embodiments, the anti-dripping device further comprises a dripping speed detection device, wherein the dripping speed detection device is fixed on the barrel cover and is arranged between the adjustable telescopic rod of the funnel and the anti-dripping water inlet pipe.

In some embodiments, monitoring devices includes mount pad, many indexes monitoring bluetooth data collector, multi-parameter data conduction ware and multi-parameter probe, the mount pad is fixed in anticreep gas evaporation monitoring bucket downside, in many indexes monitoring bluetooth data collector and the all fixed ground mount pad of multi-parameter data conduction ware, multi-parameter probe is fixed in the water sample collection glass jar, the one end of multi-parameter data conduction ware runs through the bottom of anticreep gas evaporation monitoring bucket and is connected with multi-parameter probe, many indexes monitoring bluetooth data collector and drip speed detection device and multi-parameter data conduction ware wireless connection.

In some embodiments, the monitoring device further comprises an electricity storage power supply, a system switch and a display screen, wherein the electricity storage power supply is fixed in the mounting seat, the electricity storage power supply is electrically connected with the multi-index monitoring bluetooth data collector, the multi-parameter data transmitter, the system switch and the display screen, and the display screen is electrically connected with the multi-index monitoring bluetooth data collector.

The utility model has the advantages that: the problem of the degasification that produces when having overcome multinomial monitoring such as the collection of dripping and the rate of dripping to and collect under the more slow condition of dripping, independently take water the renewal speed that produces and lead to the monitoring error problem, can be applicable to the many indexes monitoring and the water sample collection of arbitrary high drip point for a long time the efficient, realize real-time high accuracy measurement, easy and simple to handle, high-efficient practicality provides better experimental data basis for the carbon cycle characteristic of karst key area and the research of migration mechanism.

Drawings

Fig. 1 is a schematic structural view of the air-drop-preventing multi-parameter monitoring and water-collecting device for water dropping in a karst cave according to the present invention;

fig. 2 is a schematic structural view of an anti-outgassing multi-parameter monitoring and water-collecting device of the anti-outgassing evaporation monitoring barrel and the monitoring device for water dropping in the karst cave shown in fig. 1;

fig. 3 is a schematic bottom view of an adjustable universal stand of the air-shedding prevention multi-parameter monitoring and water collecting device for water dropping in the karst cave shown in fig. 1;

fig. 4 is a schematic bottom view of the anti-outgassing multi-parameter monitoring and water-collecting device for water dropping speed detection in the karst cave shown in fig. 1.

Detailed Description

The following describes the present invention in further detail with reference to the accompanying drawings.

Fig. 1 to 4 schematically show an anti-outgassing multi-parameter monitoring and water collecting device for water dropping from a karst cave according to an embodiment of the present invention.

Referring to fig. 1-4, the air-dropping prevention multi-parameter monitoring and water collecting device for water dropping in the karst cave comprises a plastic funnel 1, an adjustable telescopic rod 2 of the funnel, an air-dropping prevention evaporation monitoring barrel 3, a monitoring device 4, an adjustable universal foot stand 5 and a dropping speed detection device 6. Plasticity funnel 1 is connected with the one end of the adjustable telescopic link 2 of funnel, and the other end of the adjustable telescopic link 2 of funnel is connected with the upper end of anticreep gas evaporation monitoring bucket 3. The adjustable telescopic link 2 of funnel is the cavity form and with plasticity funnel 1 and the inside intercommunication of anticreep gas evaporation monitoring bucket 3. Monitoring devices 4 are fixed in the downside of preventing degasification evaporation monitoring bucket 3, and adjustable universal foot rest 5 is fixed in monitoring devices 4's downside.

The adjustable telescopic rod 2 of the funnel adopts a structure that an inner cylinder is sleeved on an outer cylinder in a three-section type, and a slidable button is arranged beside each section of telescopic rod interface, so that the telescopic rod can be fixed on a certain length position according to the set height.

The anti-outgassing evaporation monitoring barrel 3 comprises an opaque barrel body 31, a barrel cover 32, a water sample collecting glass tank 33, an anti-dripping water inlet pipe 34, a floating plate 35, a pumping equipment interface 36, a floating plate upper clamping block 37, a floating plate lower clamping block 38, a U-shaped drain pipe 39 and a pumping pipe 30. The water sample collecting glass tank 33, the anti-dripping water inlet pipe 34, the floating plate 35 and the water pumping pipe 35 are all positioned in the light-tight barrel body 31. The anti-outgassing evaporation monitoring barrel 3 is in an integrally sealed shape, and the barrel cover 32 is fixed at the upper end of the light-tight barrel body 31 and seals the upper end of the light-tight barrel body 31. The water sample collection glass tank 33 is fixed at the bottom inside the light-tight barrel 31, one end of the anti-dripping water inlet pipe 34 is connected with the adjustable telescopic rod 2 of the funnel, the other end of the anti-dripping water inlet pipe 34 extends into the lower end inside the water sample collection glass tank 33, the upper end of the anti-dripping water inlet pipe 34 is open, the floating plate 35 is sleeved outside the anti-dripping water inlet pipe 34, and the shape of the floating plate 35 is matched with the inner cross section of the water sample collection glass tank 33. The opaque barrel 31 may be made of glass, and the floating plate 35 may be made of paraffin.

The pumping equipment interface 36 is fixed outside the barrel cover 32, one end of the pumping pipe 30 penetrates through the floating plate 35 and extends into the water sample collecting glass tank 33, and the other end of the pumping pipe 30 is connected with the pumping equipment interface 36.

The upper floating plate clamping block 37 and the lower floating plate clamping block 38 are fixed outside the anti-dripping water inlet pipe 34, the upper floating plate clamping block 37 is positioned above the lower floating plate clamping block 38 and above the water sample collecting glass tank 33, and the floating plate 35 is positioned between the upper floating plate clamping block 37 and the lower floating plate clamping block 38. The water pumping pipe 30 is also provided with a floating plate upper clamping block 37 and a floating plate lower clamping block 38, and the floating plate upper clamping block 37 and the floating plate lower clamping block 38 on the water pumping pipe 30 are positioned on the same horizontal plane with the corresponding clamping blocks of the anti-dripping water inlet pipe 34. The floating plate 35 can move up and down between the floating plate upper fixture block 37 and the floating plate lower fixture block 38 along with the height of water.

The U-shaped drain pipe 39 is fixed at one side of the bottom of the opaque barrel 31, one end of the U-shaped drain pipe 39 is communicated with the inside of the opaque barrel 31, and the other end of the U-shaped drain pipe 39 extends out of the opaque barrel 31 and is bent upwards.

The dripping speed detection device 6 is fixed on the barrel cover 32, and the dripping speed detection device 6 is arranged between the adjustable telescopic rod 2 of the funnel and the anti-dripping and anti-splashing water inlet pipe 34. The dripping speed detecting device 6 comprises a left mounting cover 61, a right mounting cover 62, a rotating shaft 63 and a blade 64, wherein the left mounting cover 61 and the right mounting cover 62 are fixed on the barrel cover 32. The two ends of the rotating shaft 63 are rotatably connected with the left mounting cover 61 and the right mounting cover 62 respectively, and a plurality of blades 64 which are uniformly dispersed outwards are fixed on the circumferential surface of the rotating shaft 63. When water flows through the blades 64, the water flow can drive the rotating shaft 63 to rotate, the end part of the rotating shaft 63 is connected with a rotating speed sensor, and the rotating speed sensor can detect the rotating speed of the rotating shaft 63 and transmit a rotating speed signal to the monitoring device 4.

The monitoring device 4 comprises a mounting base 41, an electricity storage power supply 42, a multi-index monitoring Bluetooth data collector 43, a multi-parameter data conductor 44, a multi-parameter probe 45, a system switch 46 and a display screen 47. The mount pad 41 is fixed in the downside of anticreep gas evaporation monitoring bucket 3, and accumulate power 42, many indexes monitoring bluetooth data collector 43 and multi-parameter data conduction ware 44 are all fixed in the mount pad 41. The multi-parameter probe 45 is fixed in the water sample collecting glass tank 33, and one end of the multi-parameter data transmitter 44 penetrates through the bottom of the anti-outgassing evaporation monitoring barrel 3 and is connected with the multi-parameter probe 45.

The multi-index monitoring Bluetooth data collector 43 is wirelessly connected with the dripping speed detection device 6 and the multi-parameter data transmitter 44, and can receive the detection data transmitted by the dripping speed detection device 6 and the multi-parameter data transmitter 44. The multi-index monitoring bluetooth data collector 43 can be connected to an external receiving device such as a mobile phone or a handheld terminal and transmit the detection data to the external receiving device.

The system switch 46 is a circuit switch of the entire system. The display screen 47 is electrically connected with the multi-index monitoring Bluetooth data collector 43, and the display screen 47 is used for displaying current detection data and equipment states. The power storage power supply 42 is electrically connected with and can provide electric energy for the multi-index monitoring Bluetooth data collector 43, the multi-parameter data conductor 44, the system switch 46 and the display screen 47.

The adjustable universal foot stand 5 comprises a support base 51 and a telescopic supporting foot 52, wherein the telescopic supporting foot 52 is hinged with the support base 51. The number of the telescopic supporting legs 52 is four, so that when the telescopic supporting legs 52 are not used, the telescopic supporting legs 52 can be folded and retracted to be close to the supporting base 51.

Under the water dropping point, in combination with the situation of the floor in the hole, the adjustable universal foot stand 5 is opened 4 and only the telescopic supporting leg 52 is opened, and the supporting base 51 is adjusted to be close to the horizontal position. The funnel adjustable telescopic rod 2 is lifted and the fixing button is rotated to the locking state. The plastic funnel 1 is adjusted to the position close to the dripping point, and the shape of the plastic funnel 1 is adjusted to be close to the sediment of the dripping point as much as possible, so that the degassing of the dripping water caused by air is reduced. Observe dripping and guarantee normal circulation, drip along the adjustable telescopic link 2 of funnel and drip-proof inlet tube 34 flow into water sample collection glass tank 33, when dripping and submerge too much parameter probe 45, start through system switch 46, the observation monitoring data of accessible display screen 47 connects the bluetooth and can obtain monitoring data. After water drops continuously increase to the floating plate lower clamping block 38 in the water sample collecting glass tank 33, the floating plate 35 starts to float upwards; after the floating plate 35 floats to the upper fixture block 37 of the floating plate, the collected water overflows the water sample collecting glass tank 33 and begins to drain to the outside light-tight barrel body 31, and the surplus water is discharged to the outside through the U-shaped drain pipe 39, and when the water level is low, the floating plate 35 can also effectively prevent the air exchange between the collecting device and the outside air. By connecting the free water extraction device to the water extraction device interface 36, the drip from the cavity can be collected.

What has been described above are only some embodiments of the invention. For those skilled in the art, without departing from the inventive concept, several modifications and improvements can be made, which are within the scope of the invention.

Claims (8)

1. Anticreep gas multi-parameter monitoring and water-collecting device that karst cave was dripped, its characterized in that: including plasticity funnel (1), the adjustable telescopic link of funnel (2), anticreep gas evaporation monitoring bucket (3), monitoring devices (4) and adjustable universal foot rest (5), plasticity funnel (1) is connected with the one end of the adjustable telescopic link of funnel (2), the other end and the upper end of anticreep gas evaporation monitoring bucket (3) of the adjustable telescopic link of funnel (2) are connected, the adjustable telescopic link of funnel (2) are cavity form and with the inside intercommunication of plasticity funnel (1) and anticreep gas evaporation monitoring bucket (3), monitoring devices (4) are fixed in the downside of anticreep gas evaporation monitoring bucket (3), the downside of monitoring devices (4) is fixed in adjustable universal foot rest (5).

2. The air-escape-preventing multi-parameter monitoring and water-collecting device for water dripping in the karst cave according to claim 1, which is characterized in that the air-escape-preventing evaporation monitoring barrel (3) comprises a light-tight barrel body (31), a barrel cover (32), a water sample collecting glass tank (33), an anti-dripping water inlet pipe (34) and a floating plate (35), wherein the water sample collecting glass tank (33), the anti-dripping water inlet pipe (34) and the floating plate (35) are all arranged in the light-tight barrel body (31), the barrel cover (32) is fixed at the upper end of the light-tight barrel body (31) and seals the light-tight barrel body (31), the water sample collecting glass tank (33) is fixed at the bottom of the light-tight barrel body (31), one end of the anti-dripping water inlet pipe (34) is connected with the adjustable telescopic rod (2) of the funnel, the other end of the anti-dripping water inlet pipe (34) extends into the lower end of the water sample collecting glass tank (33, the shape of the floating plate (35) is matched with the inner cross section of the water sample collecting glass tank (33).

3. The air-escape-preventing multi-parameter monitoring and water-collecting device for water dropping at the karst cave according to claim 2, wherein the air-escape-preventing evaporation monitoring barrel (3) further comprises a water pumping pipe (30) and a water pumping equipment interface (36), the water pumping equipment interface (36) is fixed outside the barrel cover (32), one end of the water pumping pipe (30) penetrates through the floating plate (35) and extends into the water sample collecting glass tank (33), and the other end of the water pumping pipe (30) is connected with the water pumping equipment interface (36).

4. The air-shedding prevention multi-parameter monitoring and water collecting device for water dropping at the karst cave according to claim 3, wherein the air-shedding prevention evaporation monitoring barrel (3) further comprises a floating plate upper clamping block (37) and a floating plate lower clamping block (38), the floating plate upper clamping block (37) and the floating plate lower clamping block (38) are fixed outside the anti-dripping and anti-splashing water inlet pipe (34), the floating plate upper clamping block (37) is positioned above the floating plate lower clamping block (38) and above the water sample collecting glass tank (33), and the floating plate (35) is positioned between the floating plate upper clamping block (37) and the floating plate lower clamping block (38).

5. The air-escape-preventing multi-parameter monitoring and water-collecting device for water dropping from the karst cave according to claim 3, wherein the air-escape-preventing evaporation monitoring barrel (3) further comprises a U-shaped drain pipe (39), the U-shaped drain pipe (39) is fixed on one side of the bottom of the light-tight barrel body (31), and one end of the U-shaped drain pipe (39) is communicated with the inside of the light-tight barrel body (31).

6. The air-escape-preventing multi-parameter monitoring and water-collecting device for water dropping at the karst cave according to any one of claims 2-5, characterized by further comprising a dropping speed detection device (6), wherein the dropping speed detection device (6) is fixed on the barrel cover (32) and is arranged between the adjustable telescopic rod (2) of the funnel and the anti-dripping water inlet pipe (34).

7. The air-drop prevention multi-parameter monitoring and water collecting device for water dropping of the karst cave according to claim 6, the method is characterized in that: the monitoring device (4) comprises a mounting seat (41), a multi-index monitoring Bluetooth data collector (43), a multi-parameter data transmitter (44) and a multi-parameter probe (45), the mounting seat (41) is fixed on the lower side of the anti-outgassing evaporation monitoring barrel (3), the multi-index monitoring Bluetooth data collector (43) and the multi-parameter data transmitter (44) are both fixedly arranged in the mounting seat (41), the multi-parameter probe (45) is fixed in the water sample collecting glass tank (33), one end of the multi-parameter data conductor (44) penetrates through the bottom of the anti-outgassing evaporation monitoring barrel (3) and is connected with a multi-parameter probe (45), the multi-index monitoring Bluetooth data collector (43) is in wireless connection with the dripping speed detection device (6) and the multi-parameter data transmitter (44).

8. The air-release-preventing multi-parameter monitoring and water-collecting device for water dropping at the karst cave according to claim 7, characterized in that the monitoring device (4) further comprises an electricity storage power supply (42), a system switch (46) and a display screen (47), wherein the electricity storage power supply (42) is fixed in the mounting seat (41), the electricity storage power supply (42) is electrically connected with the multi-index monitoring Bluetooth data collector (43), the multi-parameter data transmitter (44), the system switch (46) and the display screen (47), and the display screen (47) is electrically connected with the multi-index monitoring Bluetooth data collector (43).

Images