CN218553351U - Sediment prevention processing system in liquid environment - Google Patents

Abstract

The utility model discloses a deposit prevention processing system in liquid environment, include: the first water pipe, the second water pipe and the third water pipe are communicated with the first water pipe and the second water pipe; the first water pipe and the second water pipe are respectively provided with a first filtering device and a second filtering device, and the communication position of the third water pipe and the first water pipe and the communication position of the third water pipe and the second water pipe are respectively positioned at the downstream of the first filtering device and the second filtering device; and a flushing water pump is arranged on the third water pipe and is used for conveying the liquid to be detected to the first water pipe or the second water pipe so as to clean the first filtering device or the second filtering device. The utility model discloses a mode of three water pipe, when one of them inlet tube washed filter equipment, perhaps when pulling filter equipment down, can continue to carry out liquid extraction and ion detection operation through another inlet tube, ensure that ion detection work can both normally go on anytime, guaranteed safety in the pit.

Description

Sediment prevention processing system in liquid environment

Technical Field

The utility model relates to an energy development technical field specifically is a deposit prevention processing system in liquid environment.

Background

Underground water in a mine is influenced by geological activities and artificial activities, and the ion concentration in the underground water can be greatly changed, so that the possibility of accidents such as flooding and the like can be known in advance by detecting the ion concentration of the underground water, and corresponding preventive measures can be taken.

At present, the ion detection of underground water is to convey liquid to be detected to an ion sensor by using a pipeline, the ion sensor generates a voltage signal corresponding to the ion concentration, and the detected liquid is discharged. Because groundwater is not filtered, and the material kind that contains is unpredictable in addition, consequently need use filter equipment filtering to remove the large granule impurity in the liquid, avoid impurity to pile up and cause the pipe blockage. However, the filter device is clogged with impurities after a long time use, and thus needs to be cleaned. The current common cleaning method is to remove the filter from the pipeline, which can cause the ion detection to be interrupted, posing a serious threat to downhole safety.

SUMMERY OF THE UTILITY MODEL

The utility model provides a sediment prevention processing system in liquid environment to solve the problem that exists among the prior art.

In order to achieve the above purpose, the utility model provides a following technical scheme: a system for the preventive treatment of deposits in a liquid environment, comprising: the first water pipe, the second water pipe and the third water pipe are communicated with the first water pipe and the second water pipe;

the first water pipe and the second water pipe are respectively provided with a first filtering device and a second filtering device, and the communication part of the third water pipe and the first water pipe and the communication part of the third water pipe and the second water pipe are respectively positioned at the downstream of the first filtering device and the second filtering device;

and a flushing water pump is arranged on the third water pipe and conveys the liquid to be detected to the first water pipe or the second water pipe so as to clean the first filtering device or the second filtering device.

In one possible implementation mode, a first electromagnetic valve and a first water pump are arranged on the first water pipe, and the first electromagnetic valve and the first water pump are both positioned at the downstream of the communication position of the first water pipe and the third water pipe; and a second electromagnetic valve and a second water pump are arranged on the second water pipe, and the second electromagnetic valve and the second water pump are both positioned at the downstream of the communication part of the second water pipe and the third water pipe.

In a possible implementation manner, the third water pipe comprises a main pipe, a first branch pipe and a second branch pipe, the flushing water pump is arranged on the main pipe, the first branch pipe is connected between the first water pipe and the main pipe, and the second branch pipe is connected between the second water pipe and the main pipe.

In a possible implementation manner, the first branch pipe and the second branch pipe are respectively provided with a third electromagnetic valve and a fourth electromagnetic valve.

In one possible implementation manner, a first magnetic scale remover is arranged on the first water pipe and is positioned upstream of the first filtering device; and a second magnetic scale remover is arranged on the second water pipe and is positioned upstream of the second filtering device.

Compared with the prior art, the utility model provides a deposit prevention processing system in liquid environment possesses following beneficial effect:

adopt the mode of three inlet tube, wash filter equipment as one of them inlet tube, perhaps when dismantling filter equipment, can continue to carry out liquid extraction and ion detection operation through another inlet tube, ensure ion detection work and can both normally go on anytime, guaranteed safety in the pit.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a system for preventing and treating sediments in a liquid environment according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Fig. 1 is a schematic structural diagram of a system for preventing and treating sediments in a liquid environment according to an embodiment of the present invention. The embodiment of the utility model provides a pair of deposit prevention processing system in liquid environment, include: the water pipe comprises a first water pipe 100, a second water pipe 200 and a third water pipe, wherein the third water pipe is communicated with the first water pipe 100 and the second water pipe 200;

the first water pipe 100 and the second water pipe 200 are respectively provided with a first filtering device 110 and a second filtering device 210, and the communication position of the third water pipe and the first water pipe 100 and the communication position of the third water pipe and the second water pipe 200 are respectively positioned at the downstream of the first filtering device 110 and the second filtering device 210;

the third water pipe is provided with a flushing water pump 301, and the flushing water pump 301 conveys the liquid to be detected to the first water pipe 100 or the second water pipe 200 so as to clean the first filtering device 110 or the second filtering device 210.

Illustratively, the first water pipe 100 and the second water pipe 200 are both connected to a device provided with an ion sensor, when the first water pipe 100 or the second water pipe 200 pumps water into the device, the ion sensor can generate a voltage signal corresponding to a target ion concentration, the control device can analyze the voltage signal to obtain ion concentration data, and the obtained ion concentration data can be displayed through a display device electrically connected with the control device, so that a manager can know the ion concentration data in time.

In the embodiment of the present invention, after the first filtering device 110 in the first water pipe 100 is blocked, the third water pipe extracts the liquid to be detected into the first water pipe 100, and performs reverse flushing on the first filtering device 110 at the downstream, so that the flushed liquid communicating impurities flow out from the water inlet of the first water pipe 100. And the second water pipe 200 continues to perform the extraction of the liquid to be detected and the ion detection, so as to ensure that the ion detection can be performed normally. The first filtering device 110 and the second filtering device 210 have the same structure and are both of a multi-layer filtering net structure, and the mesh number of the multi-layer filtering net is gradually increased along the flowing direction of the liquid, namely the aperture of the filtering net is gradually reduced, so that impurities with various sizes are filtered.

In a possible embodiment, the first water pipe 100 is provided with a first electromagnetic valve 120 and a first water pump 130, and the first electromagnetic valve 120 and the first water pump 130 are both located downstream of the communication between the first water pipe 100 and the third water pipe; the second water pipe 200 is provided with a second electromagnetic valve 220 and a second water pump 230, and the second electromagnetic valve 220 and the second water pump 230 are both positioned at the downstream of the communication position of the second water pipe 200 and the third water pipe.

Illustratively, when the first filtering device 110 in the first water pipe 100 needs to be backwashed, the first solenoid valve 120 is closed, and both the rinse water pump 301 and the second water pump 200 are started, so that the liquid entering the first water pipe 100 backwashes the first filtering device 110, but does not flow into the equipment where the ion sensor is located along the first water pipe 100, and the rinsing force on the first filtering device 110 is increased. While the liquid pumping operation in the second water pipe 200 is not affected.

Correspondingly, when the second filtering device 210 in the second water pipe 200 needs to be backwashed, the second electromagnetic valve 220 is closed, and both the rinsing water pump 301 and the first water pump 100 are started, so that the liquid entering the second water pipe 200 backwashes the second filtering device 210, and does not flow into the equipment where the ion sensor is located along the second water pipe 200, and the rinsing force on the second filtering device 210 is increased. While the liquid pumping operation in the first water pipe 100 is not affected.

In a possible embodiment, the third water pipe includes a main pipe 300, a first branch pipe 310 and a second branch pipe 320, the washing water pump 301 is disposed on the main pipe 300, the first branch pipe 310 is connected between the first water pipe 100 and the main pipe 300, and the second branch pipe 320 is connected between the second water pipe 200 and the main pipe 300.

For example, the method of connecting two branch pipes with one main pipe 300 can save the installation cost of the pipeline, and since only one filtering device in one water pipe is flushed at the same time, one of the first branch pipe 310 or the second branch pipe 320 is filled with liquid, while the other is not filled with liquid, and the flushing work of the two water pipes is not affected by one main pipe 300 and the flushing water pump 301.

In a possible embodiment, the first branch pipe 310 and the second branch pipe 320 are provided with a third solenoid valve 311 and a fourth solenoid valve 321, respectively.

Illustratively, based on the above structure, when it is required to flush the first filter device 110 in the first water pipe 100, the fourth solenoid valve 321 on the second branch pipe 320 is closed, and the third solenoid valve 311 on the first branch pipe 310 is opened, so that the liquid for flushing can only enter the first water pipe 100 through the first branch pipe 310, but not the second water pipe 200. When the second filter device 210 in the second water pipe 200 needs to be flushed, the third solenoid valve 311 of the first branch pipe 310 is closed, and the fourth solenoid valve 321 of the second branch pipe 320 is opened, so that the flushing liquid can only enter the second water pipe 200 through the second branch pipe 320, but not the first water pipe 100.

In a possible embodiment, a first magnetic scale remover 140 is arranged on the first water pipe 100, the first magnetic scale remover 140 is located upstream of the first filtering device 110; the second water pipe 200 is provided with a second magnetic scale remover 240, and the second magnetic scale remover 240 is located upstream of the second filtering device 210.

Illustratively, the magnetic scale remover can generate a strong magnetic field after being electrified, and under the action of the strong magnetic field, the condensed macromolecular groups in the liquid can be cut into small molecules, so that substances which can form deposits are re-dispersed in the liquid, and the possibility of attaching to the inner wall of the pipeline is lost.

It should be noted that, in this document, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, the use of the verb "comprise a" to define an element does not exclude the presence of another, same element in a process, method, article, or apparatus that comprises the element.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. A system for the preventive treatment of deposits in a liquid environment, comprising: the water supply device comprises a first water pipe (100), a second water pipe (200) and a third water pipe, wherein the third water pipe is communicated with the first water pipe (100) and the second water pipe (200);

a first filtering device (110) and a second filtering device (210) are respectively arranged on the first water pipe (100) and the second water pipe (200), and the communication position of the third water pipe and the first water pipe (100) and the communication position of the third water pipe and the second water pipe (200) are respectively positioned at the downstream of the first filtering device (110) and the second filtering device (210);

a flushing water pump (301) is arranged on the third water pipe, and the flushing water pump (301) conveys the liquid to be detected into the first water pipe (100) or the second water pipe (200) so as to clean the first filtering device (110) or the second filtering device (210).

2. A system for preventing and treating sediments in liquid environment as claimed in claim 1, wherein said first water pipe (100) is provided with a first electromagnetic valve (120) and a first water pump (130), said first electromagnetic valve (120) and said first water pump (130) are both located at the downstream of the connection between said first water pipe (100) and said third water pipe;

and a second electromagnetic valve (220) and a second water pump (230) are arranged on the second water pipe (200), and the second electromagnetic valve (220) and the second water pump (230) are both positioned at the downstream of the communication position of the second water pipe (200) and the third water pipe.

3. A system for the preventive treatment of sediments in a liquid environment according to claim 1, wherein said third water pipe comprises a main pipe (300), a first branch pipe (310) and a second branch pipe (320), said flushing water pump (301) being arranged on said main pipe (300), said first branch pipe (310) being connected between said first water pipe (100) and main pipe (300), said second branch pipe (320) being connected between said second water pipe (200) and main pipe (300).

4. A system for the preventive treatment of deposits in a liquid environment according to claim 3, wherein said first branch pipe (310) and said second branch pipe (320) are provided with a third solenoid valve (311) and a fourth solenoid valve (321), respectively.

5. A system for the preventive treatment of deposits in a liquid environment according to claim 1, characterised in that a first magnetic scale remover (140) is arranged on said first water pipe (100), said first magnetic scale remover (140) being located upstream of said first filtering means (110);

a second magnetic scale remover (240) is arranged on the second water pipe (200), and the second magnetic scale remover (240) is positioned at the upstream of the second filtering device (210).

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