CN114544242A

CN114544242A - Water quality monitoring and sampling device for water resource treatment and use method thereof

Info

Publication number: CN114544242A
Application number: CN202011353748.1A
Authority: CN
Inventors: 袁宏宾
Original assignee: Hunan Neite Environmental Protection Technology Co ltd
Current assignee: Hunan Neite Environmental Protection Technology Co ltd
Priority date: 2020-11-27
Filing date: 2020-11-27
Publication date: 2022-05-27

Abstract

The invention discloses a water quality monitoring sampling device for water resource management, which comprises a mounting plate, wherein the top of the mounting plate is connected with a telescopic column, the top of the telescopic column is connected with a guide block, the guide block is provided with a chute, a slide rod is connected in the chute, the slide rod is connected with a guide sleeve, the bottom of the guide sleeve is connected with a mounting sleeve, a nut is connected in the mounting sleeve, the nut is connected with a screw rod, two sides of the screw rod are connected with bearings, one side of each bearing is arranged in the telescopic column, the other side of each bearing is connected with a baffle, the baffle is fixedly arranged on the guide block, one side of each bearing is connected with a servo motor, the servo motor is arranged in the telescopic column, the bottom of the mounting sleeve is connected with a waterproof sleeve, an electric cylinder is arranged in the waterproof sleeve, the power output end of the electric cylinder is connected with a sampling cylinder, the sampling cylinder is provided with a water inlet, the upper side and the lower side of the water inlet of the sampling cylinder are fixedly connected with sealing rings, and the surface of the sampling cylinder is sleeved with a fixing sleeve, the fixed sleeve is provided with an open slot corresponding to the water inlet.

Description

Water quality monitoring and sampling device for water resource treatment and use method thereof

Technical Field

The invention belongs to the technical field of water quality sampling, and particularly relates to a water quality monitoring sampling device for water resource treatment and a using method thereof.

Background

At the treatment in-process of water resource, often need carry out quality testing to the water source, and this just needs special sampling device to carry out the sample operation to the water source, but current sampling device can only sample to the quality of water surface, and can not sample to the depths of quality of water to make the monitoring data after the sample inaccurate.

Disclosure of Invention

In view of the problems raised by the above background art, the present invention is directed to: aims to provide a water quality monitoring and sampling device for water resource treatment and a using method thereof.

In order to achieve the technical purpose, the technical scheme adopted by the invention is as follows:

a water quality monitoring sampling device for water resource treatment comprises a mounting plate, wherein a telescopic column is connected to the top of the mounting plate, a guide block is connected to the top of the telescopic column, a sliding groove is formed in the guide block, a sliding rod is connected in the sliding groove, a guide sleeve is connected to the sliding rod, a mounting sleeve is connected to the bottom of the guide sleeve, a nut is connected in the mounting sleeve, the nut is connected with a screw rod, bearings are connected to two sides of the screw rod, one side of each bearing is installed in the telescopic column, a baffle is connected to the other side of each bearing, the baffle is fixedly installed on the guide block, a servo motor is connected to one side of each bearing, the servo motor is installed in the telescopic column, a waterproof sleeve is connected to the bottom of the mounting sleeve, an electric cylinder is installed in the waterproof sleeve, a sampling cylinder is connected to the power output end of the electric cylinder, and is provided with a water inlet, the sampling tube is characterized in that sealing rings are fixedly connected to the upper side and the lower side of the water inlet of the sampling tube, a fixing sleeve is sleeved on the surface of the sampling tube, and an open slot is formed in the position, corresponding to the water inlet, of the fixing sleeve.

Further inject, the mounting panel is connected with through welded fastening with triangle-shaped boss with flexible post. Such a structural design makes the connection more secure.

Further limit, the mounting panel bottom fixedly connected with grabs ground nail. Such a structural design makes the installation more stable.

A water quality monitoring sampling use method for water resource treatment is characterized by comprising the following steps:

s1: placing the mounting plate beside the water to be sampled, controlling a servo motor to drive a screw rod to rotate, driving a nut by the screw rod, driving a mounting sleeve by the nut, and driving a guide sleeve by the mounting sleeve so as to move stably;

s2: when the mounting sleeve drives the sampling cylinder to move above the water quality, the telescopic column is controlled to drive the guide block, and the guide block drives the mounting sleeve to move downwards, so that the mounting sleeve pushes the sampling cylinder to enter the water;

s3: when the sampler barrel has certain degree of depth in water, through controlling electric cylinder, make electric cylinder promote the sampler barrel, make the sampler barrel slide downwards along fixed cover, make water inlet and open slot coincidence, thereby make water can enter into the sampler barrel from open slot and water inlet in, fill the back when the sampler barrel, once more through controlling electric cylinder, make electric cylinder drive the sampler barrel rebound, make water inlet and open slot stagger, and prevent the rivers play in the sampler barrel through two sealing washers.

The invention has the beneficial effects that; according to the invention, by arranging the sampling cylinder, when the sampling cylinder has a certain depth in water, the electric cylinder is controlled to push the sampling cylinder to slide downwards along the fixed sleeve, so that the water inlet is superposed with the open slot, water can enter the sampling cylinder from the open slot and the water inlet, and after the sampling cylinder is filled, the electric cylinder is controlled to drive the sampling cylinder to move upwards again, so that the water inlet is staggered with the open slot, and the water in the sampling cylinder is prevented from flowing out through the two sealing rings, so that the water quality sampling in deep water is facilitated, and the subsequent monitoring and investigation are facilitated.

Drawings

The invention is further illustrated by the non-limiting examples given in the accompanying drawings;

FIG. 1 is a schematic structural view of a water quality monitoring and sampling device for water resource treatment according to an embodiment of the present invention;

FIG. 2 is a schematic sectional view of a water quality monitoring and sampling device for water resource treatment according to an embodiment of the present invention

The main element symbols are as follows:

the device comprises a mounting plate 1, a telescopic column 2, a guide block 3, a sliding groove 4, a sliding rod 5, a guide sleeve 6, a mounting sleeve 7, a nut 8, a screw rod 9, a bearing 10, a baffle plate 11, a servo motor 12, a waterproof sleeve 13, an electric cylinder 14, a sampling cylinder 15, a water inlet 16, a sealing ring 17, a fixing sleeve 18, an open slot 19 and a triangular reinforcing block 20.

Detailed Description

In order that those skilled in the art can better understand the present invention, the following technical solutions are further described with reference to the accompanying drawings and examples.

As shown in fig. 1-2, the water quality monitoring and sampling device for water resource management of the present invention comprises a mounting plate 1, a telescopic column 2 connected to the top of the mounting plate 1, a guide block 3 connected to the top of the telescopic column 2, a sliding slot 4 in the guide block 3, a sliding rod 5 connected to the sliding rod 5, a guide sleeve 6 connected to the bottom of the guide sleeve 6, a mounting sleeve 7 connected to the bottom of the guide sleeve 6, a nut 8 connected to the mounting sleeve 7, a screw 9 connected to the nut 8, bearings 10 connected to both sides of the screw 9, a bearing 10 having one side installed in the telescopic column 2 and the other side connected to a baffle 11, the baffle 11 fixedly installed on the guide block 3, a servo motor 12 connected to one side of the bearing 10, the servo motor 12 installed in the telescopic column 2, a waterproof sleeve 13 connected to the bottom of the mounting sleeve 7, an electric cylinder 14 installed in the waterproof sleeve 13, and a sampling tube 15 connected to the power output end of the electric cylinder 14, the sampling tube 15 is provided with a water inlet 16, the upper side and the lower side of the water inlet 16 of the sampling tube 15 are both fixedly connected with sealing rings 17, the surface of the sampling tube 15 is sleeved with a fixing sleeve 18, and the fixing sleeve 18 is provided with an open slot 19 at the position corresponding to the water inlet 16.

When the sampling device is used, the mounting plate 1 is placed beside water to be sampled, the servo motor 12 is controlled to drive the screw rod 9 to rotate, the screw rod 9 drives the nut 8, the nut 8 drives the mounting sleeve 7, the mounting sleeve 7 drives the guide sleeve 6 to stably move, the mounting sleeve 7 drives the sampling cylinder 15 to move above the water, the telescopic column 2 is controlled to drive the guide block 3, the guide block 3 drives the mounting sleeve 7 to move downwards, so that the mounting sleeve 7 pushes the sampling cylinder 15 into water, when the sampling cylinder 15 is in water to a certain depth, the electric cylinder 14 is controlled to push the sampling cylinder 15, the sampling cylinder 15 slides downwards along the fixing sleeve 18, the water inlet 16 is superposed with the open slot 19, so that water can enter the sampling cylinder 15 from the open slot 19 and the water inlet 16, and after the sampling cylinder 15 is filled, and controlling the electric cylinder 14 again to enable the electric cylinder 14 to drive the sampling cylinder 15 to move upwards, so that the water inlet 16 is staggered with the open slot 19, and the water in the sampling cylinder 15 is prevented from flowing out through the two sealing rings 17.

Preferably, the mounting plate 1 and the telescopic column 2 are connected with a triangular reinforcing block 20 fixedly connected by welding. Such a structural design makes the connection more secure.

Preferably, the bottom of the mounting plate 1 is fixedly connected with a ground grabbing nail. Such a structural design makes the installation more stable.

s1: the mounting plate 1 is placed beside water to be sampled, the servo motor 12 is controlled to drive the screw rod 9 to rotate, the screw rod 9 drives the nut 8, the nut 8 drives the mounting sleeve 7, and the mounting sleeve 7 drives the guide sleeve 6, so that the mounting plate can stably move;

s2: when the mounting sleeve 7 drives the sampling tube 15 to move above the water quality, the telescopic column 2 drives the guide block 3 by controlling the telescopic column 2, and the guide block 3 drives the mounting sleeve 7 to move downwards, so that the mounting sleeve 7 pushes the sampling tube 15 into the water;

s3: when the sampling cylinder 15 has a certain depth in water, the electric cylinder 14 is controlled to push the sampling cylinder 15, the sampling cylinder 15 slides downwards along the fixing sleeve 18, the water inlet 16 is coincided with the open slot 19, so that water can enter the sampling cylinder 15 from the open slot 19 and the water inlet 16, after the sampling cylinder 15 is filled, the electric cylinder 14 is controlled again to drive the sampling cylinder 15 to move upwards, the water inlet 16 is staggered with the open slot 19, and the water in the sampling cylinder 15 is prevented from flowing out through the two sealing rings 17.

The foregoing embodiments are merely illustrative of the principles of the present invention and its efficacy, and are not to be construed as limiting the invention. Any person skilled in the art can modify or change the above-mentioned embodiments 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 scope of the present invention as defined in the appended claims.

Claims

1. The utility model provides a water quality monitoring sampling device is administered to water resource which characterized in that: including mounting panel (1), mounting panel (1) top is connected with flexible post (2), flexible post (2) top is connected with guide block (3), guide block (3) are equipped with spout (4), spout (4) in-connection has slide bar (5), slide bar (5) are connected with uide bushing (6), uide bushing (6) bottom is connected with installation cover (7), install cover (7) in-connection has nut (8), nut (8) are connected with lead screw (9), the both sides of lead screw (9) are connected with bearing (10), one side of bearing (10) is installed in flexible post (2), the opposite side of bearing (10) is connected with baffle (11), baffle (11) fixed mounting is on guide block (3), one side of bearing (10) is connected with servo motor (12), servo motor (12) are installed in flexible post (2), install set (7) bottom and be connected with waterproof cover (13), install electric cylinder (14) in waterproof cover (13), the power take off end of electric cylinder (14) is connected with sampler barrel (15), sampler barrel (15) are equipped with water inlet (16), the equal fixedly connected with sealing washer (17) in the upper and lower both sides of water inlet (16) of sampler barrel (15), sampler barrel (15) surface cover has fixed cover (18), fixed cover (18) are located to be equipped with open slot (19) corresponding water inlet (16).

2. The water quality monitoring and sampling device for water resource treatment according to claim 1, characterized in that: the mounting plate (1) is connected with the telescopic column (2) through a triangular reinforcing block (20) fixedly connected through welding.

3. The water quality monitoring and sampling device for water resource treatment according to claim 2, characterized in that: the bottom of the mounting plate (1) is fixedly connected with a ground grabbing nail.

4. A water quality monitoring sampling use method for water resource treatment is characterized by comprising the following steps:

s1: the mounting plate (1) is placed beside water to be sampled, the servo motor (12) is controlled to drive the screw rod (9) to rotate, the screw rod (9) drives the nut (8), the nut (8) drives the mounting sleeve (7), and the mounting sleeve (7) drives the guide sleeve (6) so as to move stably;

s2: when the mounting sleeve (7) drives the sampling tube (15) to move above water quality, the telescopic column (2) drives the guide block (3) by controlling the telescopic column (2), and the guide block (3) drives the mounting sleeve (7) to move downwards, so that the mounting sleeve (7) pushes the sampling tube (15) to enter water;

s3: when a sampling cylinder (15) has a certain depth in water, the electric cylinder (14) is controlled to enable the electric cylinder (14) to push the sampling cylinder (15), the sampling cylinder (15) slides downwards along the fixed sleeve (18), and the water inlet (16) is coincided with the open slot (19), so that water can enter the sampling cylinder (15) from the open slot (19) and the water inlet (16), after the sampling cylinder (15) is filled with water, the electric cylinder (14) is controlled again, the electric cylinder (14) drives the sampling cylinder (15) to move upwards, the water inlet (16) is staggered with the open slot (19), and water in the sampling cylinder (15) is prevented from flowing out through the two sealing rings (17).