CN116466053A - Real-time monitoring device and monitoring method for urban water environment ecological restoration - Google Patents

Abstract

The invention relates to the technical field of water environment monitoring, in particular to a real-time monitoring device and a monitoring method for urban water environment ecological restoration. It includes sampling device and sets up in the positioner at sampling device top, and sampling device includes sampling mechanism, and sampling mechanism includes the sampling box. When the river water is sampled, the river water enters one of the storage structures for storage, after one of the storage structures is full of the river water, the storage groove is sealed by the sealing plate, so that when the river water at the next depth is sampled, the two river water at the next depth are prevented from being mixed, and after one of the storage structures is full of the river water, the rotating disc is driven to rotate under the action of the lifting mechanism, the input groove is further aligned to the next connecting groove, and in the rotating process of the rotating disc, the sampling box is enabled to move in the vertical direction through the positioning device, and then the river water at the next depth is sampled, and the effects of sampling and storing the river water at different depths are achieved.

Description

Real-time monitoring device and monitoring method for urban water environment ecological restoration

Technical Field

The invention relates to the technical field of water environment monitoring, in particular to a real-time monitoring device and a monitoring method for urban water environment ecological restoration.

Background

The water environment pollution problem is increasingly serious along with economic activities of human beings and social development, the urban water environment is particularly serious, the urban population is concentrated, the crowd activity range is concentrated, the water environment pollution severely restricts the normal life and the social development of human beings, the ecological restoration of the water environment is a low-energy restoration process, the water environment needs to be detected in real time in the restoration process, the condition of the water environment is known in time, and more reasonable restoration measures are convenient to be carried out on the water environment, so a plurality of real-time monitoring devices are arranged in important rivers, reservoirs and other water flow areas, and the real-time monitoring devices are utilized for monitoring the change of the water environment in real time.

The common water environment monitoring method is to use a container to hold river water, and send the river water into a laboratory for detection, and most of the river in the city has slow flow rate, so that the river water with different depths needs to be sampled and detected, and when the river is sampled with different depths, if the river water with different depths is sampled respectively, the method is troublesome, and if the method of one-time sampling is adopted, the river water with the previous depth is easily stored in the container with the next depth in the sampling process, so that the sampling result is not accurate enough, and therefore, the real-time monitoring device and the monitoring method for ecological restoration of the urban water environment are provided.

Disclosure of Invention

The invention aims to provide a real-time monitoring device and a monitoring method for urban water environment ecological restoration, which are used for solving the problems in the background technology.

In order to achieve the above object, one of the purposes of the present invention is to provide a real-time monitoring device for ecological restoration of urban water environment, which comprises a sampling device and a positioning device arranged at the top of the sampling device, wherein the sampling device comprises a sampling mechanism, the sampling mechanism comprises a sampling box, a plurality of storage structures which are annularly arranged are arranged in the sampling box, the storage structures are used for storing water with different depths, a rotating mechanism is arranged in the sampling box and is used for guiding water flow outside the sampling box to the inside of the storage structures, a plurality of lifting mechanisms which are annularly arranged are further arranged in the sampling box, a plurality of lifting mechanisms and a plurality of storage structures are arranged in a one-to-one correspondence manner, after the water flow in the storage structures is fully stored, the lifting mechanisms seal the storage structures and drive the rotating mechanisms to rotate, and the positioning device is used for determining the positions of the sampling box.

As a further improvement of the technical scheme, the storage structure comprises a storage tank, the storage tank is arranged in the sampling box, the top of the storage tank is provided with a connecting tank, the connecting tank is used for conducting river water into the storage tank, and the connecting tank is communicated with the inside of the storage tank.

As the further improvement of this technical scheme, slewing mechanism includes the rolling disc, the rolling disc rotates the inside that sets up in the sampling box, the input groove has been seted up to the inside of sampling box, during the spread groove guides river to the holding tank, the input groove guides the inside of spread groove with the river at rolling disc top.

As the further improvement of this technical scheme, elevating system includes the lifter plate, the lifter plate slides and sets up in the inside of holding vessel, the bottom of lifter plate is equipped with the sliding wedge, the bottom of lifter plate and the laminating of the inclined plane of sliding wedge, the sliding wedge slides and sets up in the inside of sampling box, one side fixedly connected with synchronizing lever of sliding wedge, the top fixedly connected with closing plate of synchronizing lever, when river in the holding vessel is deposited fully, the closing plate seals up the holding vessel.

As a further improvement of the technical scheme, the bottom end of the rotating disc is fixedly connected with a rotating shaft, the bottom end of the rotating shaft is fixedly connected with a driving disc, and the side wall of the driving disc is fixedly connected with a plurality of driving wedges.

As a further improvement of the technical scheme, the bottom end fixedly connected with of lifter plate presses the pole, press the inclined plane laminating of the bottom of pole and drive voussoir, the bottom fixedly connected with lift spring of lifter plate, lift spring is used for giving an ascending thrust of lifter plate.

As a further improvement of the technical scheme, one side of the storage tank is provided with a communication tank, the communication tank is communicated with the storage tank, and the bottom of the communication tank is communicated with the outside of the sampling box.

As a further improvement of the technical scheme, the positioning device comprises a positioning frame, one end of the positioning frame is slidably connected with two positioning rods, the bottom end of each positioning rod is fixedly connected with a connecting frame, the connecting frame is fixedly connected with the sampling box, and the positioning rods are matched with the connecting frame to determine the position of the sampling box.

As a further improvement of the technical scheme, the top end of the rotating disc is fixedly connected with a transmission rod, the transmission rod is rotationally connected with the connecting frame, the top end of the transmission rod is fixedly connected with a threaded rod, and the threaded rod is in threaded connection with the positioning frame.

The second object of the invention is to provide a real-time monitoring method for urban water environment ecological restoration, which comprises any one of the above real-time monitoring devices for urban water environment ecological restoration, and comprises the following steps:

s1, after a sampling box is placed under the water surface, river water enters a storage structure through a rotating mechanism;

s2, after one of the storage structures is full of river water, the lifting mechanism seals the storage structure and drives the rotating mechanism to rotate.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the real-time monitoring device and the monitoring method for urban water environment ecological restoration, when river water is sampled, the river water enters one of the storage structures to be stored, after one of the storage structures is filled with the river water, the storage tank is sealed by the sealing plate, so that when the river water of the next depth is prevented from being sampled, the river water of the two depths is mixed, and after one of the storage structures is filled with the river water, the rotating disc is driven to rotate under the action of the lifting mechanism, the input groove is further aligned with the next connecting groove, in the rotating process of the rotating disc, the sampling box is enabled to move in the vertical direction through the positioning device, then the river water of the next depth is sampled, the effect of sampling and storing the river water of different depths is achieved, and after each sampling is completed, the storage tank is sealed, so that the influence on the later detection result is avoided.

2. The real-time monitoring device and the monitoring method for urban water environment ecological restoration are used for sealing the storage tank by the sealing plate after each river water sampling is completed, and communicating the communication tank with the connecting tank, so that the river water in the input tank, the connecting tank and the communication tank is communicated with the river water outside the sampling tank, and when the sampling tank moves in the vertical direction, the outside river water is fused with the river water in the input tank, the connecting tank and the communication tank, so that the condition that the river water with the previous depth is collected during the next sampling is avoided, and the collection result is not accurate.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic diagram of a sampling device according to the present invention;

FIG. 3 is a schematic diagram of a sampling mechanism according to the present invention;

FIG. 4 is a schematic view of a rotating mechanism according to the present invention;

FIG. 5 is a schematic view of a combination of several lifting mechanisms according to the present invention;

FIG. 6 is a schematic view of a lifting mechanism according to the present invention;

FIG. 7 is a schematic cross-sectional view of a sample box according to the present invention;

fig. 8 is a schematic structural view of the positioning device of the present invention.

The meaning of each reference sign in the figure is:

1. a sampling device;

11. a sampling mechanism; 111. sampling box; 112. a connecting groove; 113. a storage tank; 114. a communication groove; 12. a rotating mechanism; 121. a rotating disc; 122. an input slot; 123. a rotating shaft; 124. a drive plate; 125. a drive wedge; 13. a lifting mechanism; 131. a lifting plate; 132. pressing a pressing rod; 133. a lifting spring; 134. a sliding wedge; 135. a synchronizing lever; 136. a sealing plate;

2. a positioning device;

21. a positioning frame; 22. a positioning rod; 23. a threaded rod; 24. a connecting frame; 25. a transmission rod.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Example 1

Referring to fig. 1-8, one of the purposes of this embodiment is that in a city river, since the distance from the human society is very close, a lot of household garbage is discharged into the river, so that the river is polluted, the ecological environment in the river is seriously damaged, malodor is emitted, the living state of urban residents is influenced, the general flow rate in the city river is slow, so that the water quality at each depth is different, and the components at different depths in the city river need to be collected and analyzed, therefore, a real-time monitoring device for ecological restoration of the city water environment is provided, which comprises a sampling device 1 and a positioning device 2 arranged at the top of the sampling device 1, the sampling device 1 comprises a sampling mechanism 11, the sampling mechanism 11 comprises a sampling box 111, the sampling box 111 is used for collecting the water at different depths in the river, and a plurality of annular storage structures are arranged inside the sampling box 111, and the storage structures are used for storing the water at different depths.

In order to store the river water with different depths respectively, the storage structure comprises a storage tank 113, wherein the storage tank 113 is used for storing the river water, the storage tank 113 is arranged in the sampling box 111, a connecting tank 112 is arranged at the top of the storage tank 113, the connecting tank 112 is used for conducting the river water into the storage tank 113, the connecting tank 112 is communicated with the inside of the storage tank 113, and when water flows through the connecting tank 112, the water flows into the lifting mechanism 13 for storage.

The inside of the sampling tank 111 is provided with a rotation mechanism 12, and the rotation mechanism 12 is used for guiding the water flow outside the sampling tank 111 to the inside of the storage structure.

When the sampling box 111 is used for collecting water samples, water flow outside the sampling box 111 needs to be guided into the sampling box 111, and the rotating mechanism 12 needs to guide water flow in different storage tanks 113, so the rotating mechanism 12 comprises a rotating disc 121, the rotating disc 121 is rotatably arranged in the sampling box 111, an input groove 122 is formed in the sampling box 111, when the connecting groove 112 is used for guiding river water into the storage tanks 113, the input groove 122 is used for guiding the river water at the top of the rotating disc 121 into the connecting groove 112, the top of the rotating disc 121 is in direct contact with the river water, when the water samples are collected, the bottom of the input groove 122 is positioned at the top of one of the connecting grooves 112, at the moment, the river water at the top of the rotating disc 121 enters the input groove 122 under the influence of gravity and then enters the connecting groove 112 through the input groove 122, and then the river water enters the inside of the storage tank 113, and the river water is stored; after one of the storage tanks 113 completes the storage of the river water, the rotating disk 121 rotates, and at this time, the bottom end of the input tank 122 is positioned at the top of the other connection tank 112, so that the river water sampling of the next depth is facilitated.

The inside of the sampling box 111 is also provided with a plurality of lifting mechanisms 13 which are arranged in an annular manner, the lifting mechanisms 13 and the storage structures are arranged in a one-to-one correspondence manner, and after the water flow in the storage structures is stored fully, the lifting mechanisms 13 seal the storage structures and drive the rotating mechanism 12 to rotate.

After the river water in one of the storage tanks 113 is fully stored, the storage tanks 113 need to be sealed, therefore, the lifting mechanism 13 comprises a lifting plate 131, the lifting plate 131 is slidably arranged in the storage tanks 113, a sliding wedge block 134 is arranged at the bottom end of the lifting plate 131, the bottom end of the lifting plate 131 is attached to the inclined surface of the sliding wedge block 134, the sliding wedge block 134 is slidably arranged in the sampling box 111, one side of the sliding wedge block 134 is fixedly connected with a synchronous rod 135, the top end of the synchronous rod 135 is fixedly connected with a sealing plate 136, when the river water in the storage tanks 113 is fully stored, the sealing plate 136 seals the storage tanks 113, when the river water in the storage tanks 113 is gradually fully stored, the lifting plate 131 is pushed to move downwards under the influence of the gravity of the river water, the lifting plate 131 drives the sliding wedge block 134 to slide, and the sliding wedge block 134 drives the sealing plate 136 to move through the synchronous rod 135, so that the storage tanks 113 are sealed, and water samples with different depths in later sampling are prevented from being mixed, and the results of water samples with different depths are not accurate.

When the river water in one of the storage tanks 113 is full, the rotating disc 121 needs to be adjusted to facilitate sampling of the river water of the next depth, therefore, the bottom end of the rotating disc 121 is fixedly connected with the rotating shaft 123, the bottom end of the rotating shaft 123 is fixedly connected with the driving disc 124, and the side wall of the driving disc 124 is fixedly connected with the driving wedge blocks 125.

The bottom fixedly connected with of lifter plate 131 presses down pole 132, press the laminating of the inclined plane of pole 132 and drive voussoir 125, the bottom fixedly connected with lift spring 133 of lifter plate 131, lift spring 133 is used for giving an ascending thrust of lifter plate 131, when the river in the bin 113 is deposited fully gradually, river pressure is exerted pressure for lifter plate 131, make lifter plate 131 overcome the elasticity of lift spring 133 and move downwards, lifter plate 131 drives pressing pole 132 and moves downwards, the inclined plane cooperation of pressing pole 132 and drive voussoir 125 drives drive voussoir 125 and rotates, drive voussoir 125 drives drive dish 124 and rotates, drive dish 124 drives axis of rotation 123 and rotates 121 and rotate, be convenient for take a sample the river of next degree of depth.

After the sampling of the river water of the previous depth is completed, before the river water of the next depth is sampled, part of the river water of the previous depth is accumulated in the input groove 122, when the river water of the next depth is sampled, the river water of the two depths is mixed to influence the final detection result, therefore, the communication groove 114 is formed in one side of the storage groove 113, the communication groove 114 is communicated with the storage groove 113, the bottom of the communication groove 114 is communicated with the outside of the sampling box 111, before the river water in the storage groove 113 is fully stored, the communication groove 114 is separated from the storage groove 113 by the sealing plate 136, after the river water in the storage groove 113 is fully stored, the lifting plate 131 is sealed by the sealing plate 136, at this time, the communication groove 112 is communicated with the river water in the input groove 122, and the river water in the communication groove 114, and the river water in the communication groove 122 are communicated with the outside of the sampling box 111 in the process that the sampling box 111 moves along the vertical direction, so that the influence of the river water of different depths in the sampling of the next depth is avoided.

The positioning device 2 is used to determine the position of the sampling tank 111.

When the sampling box 111 samples river water, the depth of the sampling box 111 needs to be adjusted, the positioning device 2 comprises a positioning frame 21, one end position of the positioning frame 21 is slidably connected with two positioning rods 22, the bottom end of each positioning rod 22 is fixedly connected with a connecting frame 24, the connecting frame 24 is fixedly connected with the sampling box 111, and the positioning rods 22 and the connecting frames 24 are matched to determine the position of the sampling box 111.

The top fixedly connected with transfer line 25 of rolling disc 121, transfer line 25 and link 24 rotate and connect, the top fixedly connected with threaded rod 23 of transfer line 25, threaded rod 23 and locating rack 21 threaded connection, when rolling disc 121 rotates, drive transfer line 25 rotation, transfer line 25 drives threaded rod 23 rotation, threaded rod 23 makes link 24 and sample case 111 remove in the horizontal direction with the cooperation of locating rack 21 when rotating, after sample case 111 accomplishes the sample to the river, can make sample case 111 leave the river through rotating threaded rod 23.

The second purpose of the embodiment is to provide a real-time monitoring method for urban water environment ecological restoration, which comprises any one of the above real-time monitoring devices for urban water environment ecological restoration, and comprises the following method steps:

s1, after a sampling box 111 is placed under the water surface, river water enters a storage structure through a rotating mechanism 12;

s2, after one of the storage structures is filled with river water, the lifting mechanism 13 seals the storage structure and drives the rotating mechanism 12 to rotate.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present invention, and are not intended to limit the invention, and that various changes and modifications may be made therein without departing from the spirit and scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. A be used for urban water environment ecological restoration real-time supervision device which characterized in that: including sampling device (1) and setting up in positioner (2) at sampling device (1) top, sampling device (1) includes sampling mechanism (11), sampling mechanism (11) are including sampling box (111), the inside of sampling box (111) is equipped with a plurality of storage structures that are annular and arrange, storage structure is used for storing the water of different degree of depth, the inside of sampling box (111) is equipped with slewing mechanism (12), slewing mechanism (12) are used for guiding the outside rivers of sampling box (111) to the inside of storage structure, the inside of sampling box (111) still is equipped with a plurality of elevating system (13) that are annular and arrange, a plurality of elevating system (13) and a plurality of storage structure one-to-one setting, after the rivers in the storage structure are stored, elevating system (13) are closed storage structure and are driven slewing mechanism (12) and are rotated, positioner (2) are used for confirming the position of sampling box (111).

2. The real-time monitoring device for urban water environment ecological restoration according to claim 1, wherein: the storage structure comprises a storage tank (113), wherein the storage tank (113) is arranged inside a sampling box (111), a connecting tank (112) is arranged at the top of the storage tank (113), the connecting tank (112) is used for conducting river water into the storage tank (113), and the connecting tank (112) is communicated with the inside of the storage tank (113).

3. The real-time monitoring device for urban water environment ecological restoration according to claim 2, wherein: the rotating mechanism (12) comprises a rotating disc (121), the rotating disc (121) is rotatably arranged inside a sampling box (111), an input groove (122) is formed in the sampling box (111), and when river water is guided into a storage groove (113) by a connecting groove (112), the river water at the top of the rotating disc (121) is guided into the connecting groove (112) by the input groove (122).

4. The real-time monitoring device for urban water environment ecological restoration according to claim 1, wherein: elevating system (13) are including lifter plate (131), lifter plate (131) slide and set up in the inside of holding vessel (113), the bottom of lifter plate (131) is equipped with slide wedge (134), the bottom of lifter plate (131) is laminated with the inclined plane of slide wedge (134), slide wedge (134) slide and set up in the inside of sampling box (111), one side fixedly connected with synchronizing lever (135) of slide wedge (134), the top fixedly connected with closing plate (136) of synchronizing lever (135), when river in holding vessel (113) is deposited full, closing plate (136) seals up holding vessel (113).

5. The real-time monitoring device for ecological restoration of urban water environment according to claim 3, wherein: the bottom fixedly connected with axis of rotation (123) of rolling disc (121), the bottom fixedly connected with driving disc (124) of axis of rotation (123), the lateral wall fixedly connected with of driving disc (124) is a plurality of drive voussoir (125).

6. The real-time monitoring device for urban water environment ecological restoration according to claim 4, wherein: the bottom fixedly connected with of lifter plate (131) presses pole (132), the inclined plane laminating of the bottom of pressing pole (132) and drive voussoir (125), the bottom fixedly connected with lift spring (133) of lifter plate (131), lift spring (133) are used for giving lifter plate (131) ascending thrust.

7. The real-time monitoring device for urban water environment ecological restoration according to claim 2, wherein: a communication groove (114) is formed in one side of the storage groove (113), the communication groove (114) is communicated with the storage groove (113), and the bottom of the communication groove (114) is communicated with the outside of the sampling box (111).

8. The real-time monitoring device for ecological restoration of urban water environment according to claim 3, wherein: the positioning device (2) comprises a positioning frame (21), one end position of the positioning frame (21) is slidably connected with two positioning rods (22), the bottom end of each positioning rod (22) is fixedly connected with a connecting frame (24), the connecting frames (24) are fixedly connected with the sampling box (111), and the positioning rods (22) and the connecting frames (24) are matched to determine the position of the sampling box (111).

9. The real-time monitoring device for urban water environment ecological restoration according to claim 8, wherein: the top fixedly connected with transfer line (25) of rolling disc (121), transfer line (25) and link (24) rotate to be connected, the top fixedly connected with threaded rod (23) of transfer line (25), threaded rod (23) and locating rack (21) threaded connection.

10. The real-time monitoring method for urban water environment ecological restoration comprises the real-time monitoring device for urban water environment ecological restoration, which is characterized in that: the method comprises the following steps:

s1, after a sampling box (111) is placed under the water surface, river water enters a storage structure through a rotating mechanism (12);

s2, after one of the storage structures is full of river water, the lifting mechanism (13) seals the storage structure and drives the rotating mechanism (12) to rotate.