CN211291448U - Hydrology monitoring is with monitoring stake - Google Patents

Abstract

The utility model discloses a hydrology monitoring is with monitoring stake, including the pile body, the landing leg, pull out and insert the lead screw, the sampling tube, the left surface of pile body upper end is inlayed and is had the controller, right flank fixedly connected with solar panel of pile body upper end, the left and right sides face of pile body bottom is inlayed respectively and is had level sensor and velocity of flow sensor, the bottom sliding connection of landing leg has the slide bar, pull out the driven bevel gear of the upper end fixedly connected with who inserts the lead screw, driven bevel gear's one side meshing has the drive bevel gear, the bottom threaded connection who pulls out and inserts the lead screw has the slider, the inner wall sliding connection of slider and pile body, the bottom welding of slider has the grafting post, the bottom of grafting post runs through the pile body and outwards extends, the sampling tube is inlayed at the left side inner wall of pile body, the left surface welding of sampling. Through the cooperation setting of pulling out plug screw and grafting post, can conveniently inject the monitoring stake into the riverbed or pull out from the riverbed.

Description

Hydrology monitoring is with monitoring stake

Technical Field

The utility model relates to a hydrology monitoring technology field especially relates to a hydrology monitoring is with monitoring stake.

Background

The hydrological monitoring system is suitable for hydrological departments to carry out real-time monitoring on hydrological parameters such as rivers, lakes, reservoirs, channels, underground water and the like, and the monitoring content comprises the following steps: the hydrological monitoring system adopts a wireless communication mode to transmit monitoring data in real time, so that the working efficiency of a hydrological department can be greatly improved.

The hydrological monitoring pile is directly inserted into a river bed and is used for directly monitoring the water level, the flow velocity and the like of river water, but the conventional knocking method is adopted to insert the monitoring pile into the river bed when the water level of the river water is lowered, so that the pulling and inserting of the monitoring pile are troublesome, and therefore the hydrological monitoring pile is provided to solve the technical problem.

SUMMERY OF THE UTILITY MODEL

The utility model provides a hydrology monitoring is with pulling out of monitoring stake and inserting all comparatively trouble problem of present monitoring stake that solves above-mentioned background art and proposes.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a monitoring pile for hydrological monitoring comprises a pile body, supporting legs, a pull-plug screw rod and a sampling tube, wherein a storage battery is inlaid in the upper end of the pile body, a controller is inlaid in the left side face of the upper end of the pile body, a solar panel is fixedly connected to the right side face of the upper end of the pile body, a wireless signal transmitter is inlaid in the top of the pile body, a water level sensor and a flow velocity sensor are inlaid in the left side face and the right side face of the bottom of the pile body respectively, the supporting legs are welded on the outer surface of the bottom end of the pile body, a sliding rod is slidably connected to the bottom of the supporting legs, a spring is sleeved on the periphery of the bottom end of the sliding rod, a gasket is welded at the bottom of the sliding rod, the pull-plug screw rod is rotatably connected to the inside of the pile body, a driven bevel, the other end of pivot runs through the pile body and welds and has rotatory handle, the bottom threaded connection who pulls out and insert the lead screw has the slider, the inner wall sliding connection of slider and pile body, the bottom welding of slider has the grafting post, the bottom of grafting post runs through the pile body and outwards extends, the left side inner wall at the pile body is inlayed to the sampling tube, the left surface welding of sampling tube has a plurality of to absorb water the pipe, the other end that absorbs water the pipe runs through the pile body and outwards extends, the fixed solenoid valve that is provided with in inside that absorbs water the pipe, the top fixedly connected with suction pump of sampling tube, the suction pump is inlayed in the upper end of pile body and is located the below of controller, the delivery port fixedly connected with drain pipe of suction pump.

Furthermore, solar panel, wireless signal transmitter, controller, solenoid valve, suction pump all with battery electric connection.

Further, the wireless signal transmitter is in signal connection with the wireless signal receiving terminal.

Further, the controller comprises a control key, a single chip microcomputer, an electromagnetic valve and a control switch of the water pump.

Furthermore, the signal output ends of the water level sensor and the flow velocity sensor are in signal connection with the signal input end of the controller.

Furthermore, the water suction pipes are uniformly distributed on the outer surface of the pile body from top to bottom.

Furthermore, the insertion column is connected with the bottom of the pile body in a sliding mode.

Furthermore, the number of the supporting legs is at least three, and the supporting legs are distributed in a central symmetry mode by taking the axis of the pile body as the center.

Compared with the prior art, the utility model discloses the beneficial effect who realizes:

through pulling out the cooperation setting of inserting lead screw and grafting post, can conveniently inject the monitoring stake into the riverbed or extract from the riverbed, set up through the cooperation of landing leg and slide bar, can improve the stability of monitoring stake, prevent that monitoring stake from receiving rivers influence and appearing crooked, through the cooperation setting of sampling tube and suction pump, can very conveniently carry out the water sample to the different degree of depth of river.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a partially enlarged schematic view of a portion a of fig. 1 according to the present invention.

Fig. 3 is a partially enlarged schematic view of the point B of fig. 1 according to the present invention.

In FIGS. 1-3: the device comprises a pile body 1, a support leg 2, a sliding rod 3, a spring 4, a gasket 5, a solar panel 6, a wireless signal transmitter 7, a controller 8, a storage battery 9, a pull-plug screw rod 10, a sliding block 11, a plug-in column 12, a water level sensor 13, a flow rate sensor 14, a sampling tube 15, a water suction tube 16, an electromagnetic valve 1601, a water suction pump 17, a water drainage tube 18, a rotating shaft 19, a rotating handle 20, a driving bevel gear 21 and a driven bevel gear 22.

Detailed Description

The following description is provided for illustrative purposes, and other advantages and features of the present invention will become apparent to those skilled in the art from the following detailed description.

It should be understood that the structure, ratio, size and the like shown in the drawings attached to the present specification are only used for matching with the content disclosed in the specification, so as to be known and read by those skilled in the art, and are not used for limiting the limit conditions that the present invention can be implemented, so that the present invention has no technical essential meaning, and any structure modification, ratio relationship change or size adjustment should still fall within the scope that the technical content disclosed in the present invention can cover without affecting the function that the present invention can produce and the purpose that the present invention can achieve. Meanwhile, the terms such as "upper", "lower", "left", "right", "middle" and "one" used in the present specification are for convenience of description, and are not intended to limit the scope of the present invention, and changes or adjustments of the relative relationship thereof may be made without substantial technical changes, and the present invention is also regarded as the scope of the present invention.

Please refer to fig. 1 to 3:

the utility model provides a hydrology monitoring is with monitoring stake, including pile body 1, landing leg 2, pull out and insert lead screw 10, sampling tube 15, carry out detailed description to each part of a hydrology monitoring is with monitoring stake below:

a storage battery 9 is embedded in the upper end of the pile body 1, a controller 8 is embedded on the left side surface of the upper end of the pile body 1, a solar panel 6 is fixedly connected on the right side surface of the upper end of the pile body 1, a wireless signal transmitter 7 is embedded on the top of the pile body 1, and a water level sensor 13 and a flow velocity sensor 14 are respectively embedded on the left side surface and the right side surface of the bottom of the pile body 1;

specifically, the solar panel 6 can convert absorbed solar energy into electric energy to be stored in the storage battery 9, so that the storage battery 9 can provide power for each electrical element in the monitoring pile, the water level sensor 13 and the flow velocity sensor 14 can monitor the water level and the flow velocity of river water in real time, convert information of the water level and the flow velocity into electric signals and send the electric signals to the controller 8, then the controller 8 automatically sends the information to the wireless signal receiving terminal through the wireless signal transmitter 7, so that the water level and the flow velocity of the river water can be monitored in real time, and the water pump 17 and the electromagnetic valve 1601 can be manually opened or closed through a control switch on the controller 8;

the supporting leg 2 is welded on the outer surface of the bottom end of the pile body 1, the bottom of the supporting leg 2 is connected with a sliding rod 3 in a sliding mode, a spring 4 is sleeved on the periphery of the bottom end of the sliding rod 3, and a gasket 5 is welded at the bottom of the sliding rod 3;

specifically, the supporting legs 2 can ensure the stability of the pile body 1 in water and prevent the pile body 1 from being inclined during splicing, and the supporting legs 2 have certain telescopic function when being supported by the cooperation of the sliding rods 3 and the springs 4, so that the supporting legs 2 can stably support the pile body 1 on uneven riverbeds, and the gaskets 5 can improve the contact area between the supporting legs 2 and the riverbeds and prevent the supporting legs 2 from sinking into the riverbeds;

the pulling and inserting screw rod 10 is rotatably connected inside the pile body 1, the upper end of the pulling and inserting screw rod 10 is fixedly connected with a driven bevel gear 22, one side of the driven bevel gear 22 is meshed with a driving bevel gear 21, one end face of the driving bevel gear 21 is welded with a rotating shaft 19, the other end of the rotating shaft 19 penetrates through the pile body 1 and is welded with a rotating handle 20, the bottom end of the pulling and inserting screw rod 10 is in threaded connection with a sliding block 11, the sliding block 11 is in sliding connection with the inner wall of the pile body 1, the bottom of the sliding block 11 is welded with an inserting column 12, and the bottom of the inserting column 12 penetrates through;

specifically, when the pile body 1 is fixed on the riverbed, the rotating handle 20 is manually rotated and the rotating shaft 19 drives the driving bevel gear 21 to rotate, and the driving bevel gear 21 drives the driven bevel gear 22 engaged with the driving bevel gear to rotate, because the driven bevel gear 22 is fixedly connected to the plugging lead screw 10, the driven bevel gear 22 drives the plugging lead screw 10 to rotate, when the plugging screw rod 10 rotates, the sliding block 11 screwed at the bottom end of the plugging screw rod 10 moves up and down in the pile body 1, and the sliding block 11 drives the plugging column 12 to move up and down, when the inserting column 12 descends downwards, it will be inserted into the river bed, so as to fix the pile body 1 in the river bed, when the plugging column 12 rises, the monitoring pile can be pulled out from the riverbed, so that the monitoring pile can be conveniently and quickly installed in the riverway through the pulling and plugging structure of the monitoring pile;

the sampling pipe 15 is embedded in the inner wall of the left side of the pile body 1, a plurality of water suction pipes 16 are welded on the left side face of the sampling pipe 15, the other ends of the water suction pipes 16 penetrate through the pile body 1 and extend outwards, an electromagnetic valve 1601 is fixedly arranged inside each water suction pipe 16, a water suction pump 17 is fixedly connected to the top of the sampling pipe 15, the water suction pump 17 is embedded in the upper end of the pile body 1 and located below the controller 8, and a water outlet of the water suction pump 17 is fixedly connected with a water discharge pipe 18;

it is specific, absorb water pipe 16 can absorb river and discharge into in intake pipe 15, and because absorb water pipe 16 from top to bottom evenly distributed on intake pipe 15, so every not high absorb water pipe 16 can sample the river of the different degree of depth, with this when needing to carry out the water sample to the river, firstly through controller 8 manual start suction pump 17, then rethread controller 8 manual open the required sample depth absorb water on the pipe 16 corresponding solenoid valve 1601, then suction pump 17 samples the water of this degree of depth through sampling pipe 15 and intake pipe 16, then suction pump 17 discharges the sample water through drain pipe 18, then use the sampling household utensils to collect alright with the water sample of drain pipe 18 exhaust.

The above embodiments are merely illustrative of the principles and effects of the present invention, and are not to be construed as limiting the invention. Modifications and variations can be made to the above-described embodiments by those skilled in the art without departing from the spirit and scope of the present invention. Accordingly, it is intended that all equivalent modifications or changes which may be made by those skilled in the art without departing from the spirit and technical spirit of the present invention be covered by the claims of the present invention.

Claims (8)

1. The utility model provides a hydrology monitoring is with monitoring stake, includes pile body (1), landing leg (2), pulls out and inserts lead screw (10), sampling tube (15), its characterized in that:

a storage battery (9) is inlaid in the upper end of the pile body (1), a controller (8) is inlaid in the left side face of the upper end of the pile body (1), a solar panel (6) is fixedly connected to the right side face of the upper end of the pile body (1), a wireless signal transmitter (7) is inlaid in the top of the pile body (1), and a water level sensor (13) and a flow velocity sensor (14) are inlaid in the left side face and the right side face of the bottom of the pile body (1) respectively;

the supporting legs (2) are welded on the outer surface of the bottom end of the pile body (1), the bottoms of the supporting legs (2) are connected with sliding rods (3) in a sliding mode, springs (4) are sleeved on the peripheries of the bottom ends of the sliding rods (3), and gaskets (5) are welded at the bottoms of the sliding rods (3);

the pulling and inserting screw rod (10) is rotatably connected inside the pile body (1), a driven bevel gear (22) is fixedly connected to the upper end of the pulling and inserting screw rod (10), a driving bevel gear (21) is meshed with one side of the driven bevel gear (22), a rotating shaft (19) is welded to one end face of the driving bevel gear (21), the other end of the rotating shaft (19) penetrates through the pile body (1) and is welded with a rotating handle (20), a sliding block (11) is connected to the bottom end of the pulling and inserting screw rod (10) in a threaded manner, the sliding block (11) is in sliding connection with the inner wall of the pile body (1), an inserting column (12) is welded to the bottom of the sliding block (11), and the bottom of the inserting column (12) penetrates through the pile body (1) and extends outwards;

sample tube (15) are inlayed at the left side inner wall of pile body (1), the left surface welding of sample tube (15) has a plurality of to absorb water pipe (16), the other end that absorbs water pipe (16) runs through pile body (1) and outside extension, the fixed solenoid valve (1601) that is provided with in inside of absorbing water pipe (16), the top fixedly connected with suction pump (17) of sample tube (15), suction pump (17) are inlayed in the upper end of pile body (1) and are located the below of controller (8), the delivery port fixedly connected with drain pipe (18) of suction pump (17).

2. The monitoring pile for hydrological monitoring according to claim 1, wherein: solar panel (6), wireless signal transmitter (7), controller (8), solenoid valve (1601), suction pump (17) all with battery (9) electric connection.

3. The monitoring pile for hydrological monitoring according to claim 1, wherein: the wireless signal transmitter (7) is in signal connection with the wireless signal receiving terminal.

4. The monitoring pile for hydrological monitoring according to claim 1, wherein: the controller (8) comprises control keys, a single chip microcomputer, an electromagnetic valve (1601) and a control switch of the water suction pump (17).

5. The monitoring pile for hydrological monitoring according to claim 1, wherein: and the signal output ends of the water level sensor (13) and the flow velocity sensor (14) are in signal connection with the signal input end of the controller (8).

6. The monitoring pile for hydrological monitoring according to claim 1, wherein: the water suction pipes (16) are uniformly distributed on the outer surface of the pile body (1) from top to bottom.

7. The monitoring pile for hydrological monitoring according to claim 1, wherein: the inserting column (12) is connected with the bottom of the pile body (1) in a sliding mode.

8. The monitoring pile for hydrological monitoring according to claim 1, wherein: the number of the supporting legs (2) is at least three, and the supporting legs are distributed in a central symmetry mode by taking the axis of the pile body (1) as the center.

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