CN214585334U - Remote multi-parameter water quality monitor - Google Patents

Abstract

The utility model discloses a remote multi-parameter water quality monitor, which comprises a frame body, a monitoring device and a traction structure; the bottom of the frame body is of a pointed cone structure, and the part of the frame body adjacent to the pointed cone structure is a water body collecting section; the part of the frame body above the water body acquisition section is a sealing section; the monitoring device comprises an acquisition part and an electronic element part connected with the acquisition part; the collection end of the collection part is exposed to the water collection section, and the electronic element part is completely sealed and arranged in the sealing section. The utility model discloses the grid structure on the section is gathered to well water has avoided the suspended solid to the data acquisition's of monitoring devices collection portion influence when guaranteeing water free flow, has improved data monitoring's stability. Meanwhile, the spiral structure is arranged on the outer peripheral side of the grating structure, the effect of shielding suspended matters is further enhanced, and the spiral structure is combined with the pointed cone structure at the bottom of the frame body, so that the submergence of the monitoring device is facilitated. By sealing the electronic component part at the sealing section, short circuit effects are avoided.

Description

Remote multi-parameter water quality monitor

Technical Field

The utility model relates to a water quality monitoring equipment technical field, more specifically relates to a long-range multi-parameter water quality monitoring appearance.

Background

Water is a source of life, people can not leave water in life and production activities, and the quality of drinking water is closely related to the health of people. With the development of social economy, scientific progress and improvement of the living standard of people, the requirements of people on the water quality of drinking water are continuously improved, and the water quality standard of the drinking water is correspondingly continuously developed and improved. Under the condition of using a matched reagent, the multi-parameter water quality detector can directly put a sample or a diluted solution into an instrument for quantitative water quality detection without preparing a standard solution and drawing a standard curve, and has accurate water quality detection result and simple and convenient operation. In order to detect the water quality at the bottom of the river water body, a multi-parameter water quality monitor is required to go deep into the water body, and then the data detected in real time are transmitted to the land through a remote information transmission module. The conventional monitor for deep water generally needs an auxiliary frame body arranged outside the monitor, so that the monitor can be deep into the water smoothly. However, the monitor will encounter the suspended matter in the water body when penetrating into the water body, and the suspended matter is easy to block the water body near the data acquisition end, which causes interference to the monitoring and is also not beneficial to the submergence of the monitor. In addition, the inside liquid free flow of current monitor support body leads to causing the monitor electronic component because the trouble that the infiltration takes place easily, needs often to overhaul and maintain.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a first aim at to above-mentioned defect and not enough, provide a dive smoothly, prevent that the suspended solid blocks up the long-range multi-parameter water quality monitoring appearance that disturbs, adopt seal structure to guarantee that the electronic component part avoids the infiltration.

In order to achieve the above object, the utility model discloses a specific technical scheme be:

the utility model discloses a remote multi-parameter water quality monitor, which comprises a frame body, a monitoring device arranged in the frame body and a traction structure which is connected with the top of the frame body and can rotate around an axis along with the frame body; the bottom of the frame body is of a pointed cone structure, and the part, adjacent to the pointed cone structure, of the frame body is a water body acquisition section which is used for providing a free flowing space of a water body for water quality acquisition; the part of the frame body above the water body acquisition section is a sealing section for sealing the monitoring device to prevent water body from entering; the monitoring device comprises an acquisition part and an electronic element part connected with the acquisition part; the collection end of the collection part is exposed to the water collection section, and the electronic element part is completely sealed and arranged in the sealing section.

In order to better shield suspended matters and simultaneously facilitate the submergence of the frame body, the water body collecting section comprises a grid structure and a spiral structure arranged on the outer peripheral side of the grid structure. Further, for better submergence, the spiral structure is composed of spiral sheets with the spiral diameters decreasing from top to bottom.

In order to facilitate the recovery and the placement of the frame body, the frame body is symmetrically provided with connecting lugs close to the top end part, and the connecting lugs are flexibly connected with the traction structure.

For better putting in the frame body, the traction structure comprises a lower rotary shaft connecting piece connected with the connecting lug through a rope and an upper rotary shaft connecting piece rotationally connected with the lower rotary shaft connecting piece. Because the support body bottom is the pointed cone structure, including helical structure, support body and monitoring devices are the easy rotatory dive of dive in-process, for the moment of torsion of release traction rope, will pull the structure and set the lower pivot connecting piece and the upper pivot connecting piece that can relatively rotate into. Further, for better realization relative rotation, the inside spout that is equipped with mutually supporting of lower pivot connecting piece and last pivot connecting piece realizes relative rotation through the inside slider that sets up of spout. Furthermore, the bottom of the lower rotating shaft connecting piece is provided with a lower connecting lug flexibly connected with the connecting lug; the top of the upper rotating shaft connecting piece is provided with an upper connecting lug, and the upper connecting lug is fastened on the upper connecting lug through a rope to realize a traction frame body.

As a further technical scheme of the utility model, the top of support body is equipped with the sealed lid with support body threaded connection.

As a further technical solution of the present invention, the electronic component part includes a communication unit and a parameter monitoring unit which are electrically connected; and the data is transmitted to the land through the communication unit so as to realize unmanned remote water quality monitoring.

The utility model discloses in communication unit and parameter monitoring unit be conventional technology and select, this application has only utilized its inherent attribute, does not make the improvement here.

Compared with the prior art, the utility model, following beneficial effect has:

the utility model discloses the grid structure on the section is gathered to well water has avoided the suspended solid to the data acquisition's of monitoring devices collection portion influence when guaranteeing water free flow, has improved data monitoring's stability. Meanwhile, the spiral structure is arranged on the outer peripheral side of the grating structure, the effect of shielding suspended matters is further enhanced, and the spiral structure is combined with the pointed cone structure at the bottom of the frame body, so that the submergence of the monitoring device is facilitated. Through sealing the electronic component part and arranging at the sealing section, the short circuit influence caused by water seepage of the electronic component part is avoided.

The present invention will be further described with reference to the accompanying drawings.

Drawings

Fig. 1 is a schematic structural diagram of a frame body in a preferred embodiment of the present invention.

Fig. 2 is a front view structure diagram of the frame body in the preferred embodiment of the present invention.

Fig. 3 is a schematic sectional view of a frame body according to a preferred embodiment of the present invention.

Fig. 4 is a perspective view of a traction structure in a preferred embodiment of the present invention.

Fig. 5 is a schematic cross-sectional view of a traction structure in a preferred embodiment of the present invention.

Description of reference numerals:

the device comprises a frame body 1, a pointed cone structure 11, a water body collection section 12, a sealing section 13, a connecting lug 14, a grid structure 121, a spiral structure 122, a spiral sheet 1221, a monitoring device 2, a collection part 21, a collection end 211, an electronic component part 22, a traction structure 3, a lower rotating shaft connecting piece 31, an upper rotating shaft connecting piece 32, a sliding chute 33, a lower connecting lug 311, an upper connecting lug 321 and a sealing cover 4.

Detailed Description

The present invention is further explained and illustrated by the following embodiments, it should be understood that the following embodiments are for the purpose of making the technical solution of the present invention clearer and easier to understand, and do not limit the scope of the claims.

As shown in fig. 1, the remote multi-parameter water quality monitor of the present invention comprises a frame body (1), a monitoring device 2 arranged inside the frame body 1, and a traction structure 3 connected with the top of the frame body 1 and capable of rotating around an axis along with the frame body 1; the bottom of the frame body 1 is a pointed cone structure 11, and the part of the frame body 1 adjacent to the pointed cone structure 11 is a water body acquisition section 12 for providing a free flowing space of a water body for water quality acquisition; the part of the frame body 1 above the water body acquisition section 12 is a sealing section 13 for sealing the monitoring device to prevent water body from entering; the monitoring device 2 comprises an acquisition part 21 and an electronic component part 22 connected with the acquisition part 21; the collection end 211 of the collection part 21 is exposed to the water body collection section 12, and the electronic component part 22 is completely sealed and arranged in the sealing section 13.

As shown in fig. 1, in a preferred embodiment, in order to better shield the suspended matter and facilitate the submergence of the frame body, the water collecting section 12 includes a grid structure 121 and a spiral structure 122 disposed on the outer circumferential side of the grid structure 121. Further, for better submergence, the spiral structure 122 is composed of spiral pieces 1221 with gradually decreasing spiral diameters from top to bottom.

In a preferred embodiment, in order to facilitate the retrieval and placement of the frame body, the frame body 1 is symmetrically provided with attachment lugs 14 near the top end portion, and the attachment lugs 14 are flexibly connected with the traction structure 3.

In a preferred embodiment, as shown in fig. 1 to 5, for better putting in the frame body, the traction structure 3 comprises a lower shaft connector 31 connected with the connecting lug 14 through a rope, and an upper shaft connector 32 rotatably connected with the lower shaft connector 31. Because the support body bottom is the pointed cone structure, including helical structure, support body and monitoring devices are the easy rotatory dive of dive in-process, for the moment of torsion of release traction rope, will pull the structure and set the lower pivot connecting piece and the upper pivot connecting piece that can relatively rotate into. Further, in order to better realize the relative rotation, the sliding grooves 33 which are matched with each other are arranged inside the lower rotating shaft connecting piece 31 and the upper rotating shaft connecting piece 32, and the sliding blocks are arranged inside the sliding grooves 33 to realize the relative rotation. Further, the bottom of lower shaft coupling member 31 is provided with lower coupling lugs 311 flexibly coupled with coupling lugs 14; the top of the upper rotating shaft connecting piece 32 is provided with an upper connecting lug 321, and the upper connecting lug 321 is fastened by a rope to realize the towing bracket body 1. The electronic component part 22 comprises a communication unit and a parameter monitoring unit which are electrically connected; and the data is transmitted to the land through the communication unit so as to realize unmanned remote water quality monitoring.

The utility model discloses a working method does:

the sealing cover is opened, the monitoring device is placed into the sealing section, a through hole which only exposes the collecting end is formed in the joint of the water body collecting section and the sealing section, and a sealing structure is arranged at the through hole to guarantee sealing. Screwing up sealed lid and tie the rope on last connecting lug, connecting lug also passes through the rope with the connecting lug on the support body down and is connected, at the support body decline in-process, because helical structure overcomes aquatic resistance, the rotation can take place for the support body, goes up the pivot connecting piece and releases torsion with the rotation of support body with lower pivot connecting piece this moment, and towed rope can not knot, is favorable to the dive of support body.

The present invention has been described in terms of embodiments, but not limitations, and other variations of the disclosed embodiments, as would be readily apparent to one skilled in the art, are intended to be included within the scope of the present invention as defined in the following claims, in view of the description of the present invention.

Claims (9)

1. A remote multi-parameter water quality monitor is characterized in that: comprises a frame body (1), a monitoring device (2) arranged in the frame body (1) and a traction structure (3) which is connected with the top of the frame body (1) and can rotate around an axis along with the frame body (1); the bottom of the frame body (1) is a pointed cone structure (11), and the part, adjacent to the pointed cone structure (11), on the frame body (1) is a water body acquisition section (12) for providing a water body free flowing space for water quality acquisition; the part of the frame body (1) above the water body acquisition section (12) is a sealing section (13) for sealing the monitoring device to prevent water body from entering; the monitoring device (2) comprises an acquisition part (21) and an electronic component part (22) connected with the acquisition part (21); the collection end (211) of the collection part (21) is exposed out of the water body collection section (12), and the electronic element part (22) is completely sealed and arranged in the sealing section (13).

2. The remote multiparameter water quality monitor according to claim 1, wherein: the water body collecting section (12) comprises a grid structure (121) and a spiral structure (122) arranged on the outer periphery side of the grid structure (121).

3. The remote multiparameter water quality monitor according to claim 2, wherein: the spiral structure (122) is composed of spiral sheets (1221) with the spiral diameters decreasing from top to bottom in sequence.

4. The remote multiparameter water quality monitor according to claim 1, wherein: the frame body (1) is provided with connecting lugs (14) close to the top end portion symmetrically, and the connecting lugs (14) are flexibly connected with the traction structure (3).

5. The remote multiparameter water quality monitor according to claim 4, wherein: the traction structure (3) comprises a lower rotating shaft connecting piece (31) connected with the connecting lug (14) through a rope, and an upper rotating shaft connecting piece (32) rotatably connected with the lower rotating shaft connecting piece (31).

6. The remote multiparameter water quality monitor according to claim 5, wherein: lower pivot connecting piece (31) and last pivot connecting piece (32) are inside to be equipped with spout (33) of mutually supporting, realize relative rotation through inside setting up the slider in spout (33).

7. The remote multiparameter water quality monitor according to claim 5 or 6, wherein: the bottom of the lower rotating shaft connecting piece (31) is provided with a lower connecting lug (311) flexibly connected with the connecting lug (14); the top of the upper rotating shaft connecting piece (32) is provided with an upper connecting lug (321), and the upper connecting lug (321) is fastened through a rope to realize the traction frame body (1).

8. The remote multiparameter water quality monitor according to claim 1, wherein: the top of the frame body (1) is provided with a sealing cover (4) which is in threaded connection with the frame body (1).

9. The remote multiparameter water quality monitor according to claim 1, wherein: the electronic component part (22) comprises a communication unit and a parameter monitoring unit which are electrically connected; and the data is transmitted to the land through the communication unit so as to realize unmanned remote water quality monitoring.

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