CN220609267U - Filter with on-line brine monitoring - Google Patents

Abstract

The utility model discloses a filter with online brine monitoring, which relates to the technical field of brine filtration, and comprises a filter body and a brine monitoring device, wherein the filter body and the brine monitoring device are connected with each other through a water pump; the brine monitoring device consists of a first brine monitoring cylinder and a second brine monitoring cylinder, and the first brine monitoring cylinder is connected with the second brine monitoring cylinder through a flange plate; the second saline water monitoring cylinder is internally provided with a water injection groove, the bottom of the water injection groove is provided with four filtered water flowing grooves, and the filtered water flowing grooves are internally provided with monitoring mechanisms. The filter body of the utility model filters the brine and then conveys the brine into the water injection tank through the water pump, the filtered water enters the filtered water flowing through the tank, the water is continuously flushed, the water in the filtered water flowing through the tank is continuously updated, and the water source in the filtered water flowing through the tank is stirred by the stirring blades and the trapezoid stirring rod, so that the filtered water is stirred and mixed, and the data monitored by the brine concentration monitor can be more accurate.

Description

Filter with on-line brine monitoring

Technical Field

The utility model relates to the technical field of brine filtration, in particular to a filter with online brine monitoring.

Background

The brine filter is a water treatment device using reverse osmosis technology, and its principle is to push the water pressure containing impurities onto a reverse osmosis membrane, thereby filtering the impurities therein and obtaining high purity water.

In the treatment, firstly, pretreatment is needed to remove impurities in water, such as coagulation, precipitation, ozone disinfection and the like; after pretreatment, the water enters a brine filter, fine particulate matters in the water are removed through filtration of a plurality of filter screens, and the water filtered by the plurality of filter screens is filtered through a reverse osmosis membrane to remove salt, heavy metals and bacterial plasmas in the water, so that the water with high purity is obtained.

A part of particulate matters are deposited at the bottom of the filter screen of the brine filter, and after the equipment is used for a long time, the filter screen needs to be replaced and cleaned frequently so as to prevent the accumulated particulate matters from increasing and affecting the filtering function of the filter screen, but the replacement and cleaning times of the filter screen are increased and the working efficiency is affected; the filtration effect of reverse osmosis membrane can drop after long-term use, through monitoring the filtration effect in order to observe reverse osmosis membrane to the salt solution after filtering, but traditional salt solution monitor monitors the filtered water that flows through in the passageway, and this kind of monitoring data is single, appears the error easily, influences the monitoring data result.

Disclosure of Invention

The present utility model is directed to a filter with on-line brine monitoring to solve the above-mentioned problems.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the filter with the on-line brine monitoring function comprises a filter body and a brine monitoring device, wherein the filter body and the brine monitoring device are connected with each other through a water pump; the brine monitoring device consists of a first brine monitoring cylinder and a second brine monitoring cylinder, and the first brine monitoring cylinder is connected with the second brine monitoring cylinder through a flange plate; the second saline water monitoring cylinder is internally provided with a water injection groove, the bottom of the water injection groove is provided with four filtered water flowing grooves, and the filtered water flowing grooves are internally provided with monitoring mechanisms.

The monitoring mechanism comprises a monitor insertion hole and a connecting shaft, wherein the monitor insertion hole is formed in the inner wall of the filtered water flow trough, and a brine concentration monitor is inserted into the monitor insertion hole; the connecting shaft is sequentially fixed with a trapezoid stirring rod and stirring blades.

The bottom of the filter body is provided with a through groove, the inner wall of the through groove is provided with a turnover fan blade, the bottom of the turnover fan blade is provided with a storage groove, and the storage groove is arranged in the particle collecting box.

By adopting the technical scheme, the structures of the inside of each filtered water flowing through the tank are the same, and the filtered water flowing through the inside of the tank is monitored by the four brine concentration monitors so as to obtain accurate filtered water brine concentration data; the turnover fan blades are arranged on the inner wall of the filtering water flow channel through the connecting rods.

Preferably, the reverse osmosis membrane group and the filter screen are sequentially installed in the filter body, the water inlet pipe is installed on one side of the outer portion of the filter body, and the particle removal motor is installed on the other side of the filter body.

Preferably, the first rotary blade and the second rotary blade are mounted on the output shaft of the particle removal motor, and the first rotary blade and the second rotary blade are both disposed inside the filter body.

By adopting the technical scheme, the second rotary blade is provided with two blades; the second rotating blade is used for stirring the turnover fan blade, so that the particulate matters on the turnover fan blade are pushed into the storage groove.

Preferably, a stirring motor is installed at the top of the first salt water monitoring cylinder, and an output shaft of the stirring motor is connected with the first stirring gear in an inserting mode.

Preferably, the stirring gear I is in meshed connection with the stirring gear II, and the stirring gear II is spliced with the connecting shaft.

By adopting the technical scheme, the number of the stirring gears II is four, and the stirring gears I drive the stirring gears II to rotate, so that the corresponding connecting shafts are also four.

Preferably, a water outlet pipe is fixed on the surface of the second brine monitoring cylinder.

By adopting the technical scheme, compared with the prior art, the utility model has the following technical progress:

1. the utility model provides a filter with on-line brine monitoring, which is characterized in that a filter body is used for filtering brine and then conveying the filtered brine into a water injection tank through a water pump, the filtered water enters the filtered water after flowing through the tank, the water in the filtered water flowing through the tank is continuously flushed, the water in the filtered water flowing through the tank is continuously updated, and a water source in the filtered water flowing through the tank is stirred through a stirring blade and a trapezoid stirring rod, so that the filtered water is stirred and mixed, and the data monitored by a brine concentration monitor can be more accurate.

2. The utility model provides a filter with on-line brine monitoring, the number of filtered water flowing through a tank is four, and the values measured by four brine concentration monitors arranged in the filter are compared and the average value is obtained, so that accurate data are obtained.

3. The utility model provides a filter with on-line brine monitoring, wherein particulate matters accumulated at the bottom of a filter screen can fall onto a turnover fan blade in a filter body, and the turnover fan blade is driven by a rotating blade II to rotate, so that the particulate matters on the surface of the turnover fan blade fall into a particulate collecting box to be uniformly collected, the use of the filter screen is prevented from being influenced, and the disassembly and cleaning times of the filter screen can be reduced.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic view showing a front view of a filter body according to the present utility model;

FIG. 3 is a schematic view of a partially enlarged cross-sectional structure of a filter body according to the present utility model;

FIG. 4 is a schematic diagram showing a front view of a brine monitoring device according to the present utility model;

fig. 5 is a schematic diagram of a two-dimensional structure of a brine monitoring column according to the present utility model.

In the figure: 1. a filter body; 11. a reverse osmosis membrane group; 12. a filter screen; 13. a through groove; 14. a water inlet pipe; 2. a first brine monitoring column; 21. a stirring motor; 22. stirring gear I; 3. a second brine monitoring column; 31. a water injection groove; 32. filtering water flows through the groove; 33. a monitor insertion hole; 34. a water outlet pipe; 4. a water pump; 5. a particle removal motor; 51. rotating the first blade; 52. rotating the second blade; 6. a particle collection box; 61. a storage tank; 7. stirring gear II; 71. a connecting shaft; 72. stirring blades; 73. a trapezoidal stirring rod; 8. a brine concentration monitor; 9. and turning over the fan blade.

Detailed Description

The utility model is further illustrated by the following examples:

as shown in fig. 1, the present utility model provides a filter with on-line brine monitoring, comprising a filter body 1 and a brine monitoring device, wherein the filter body 1 and the brine monitoring device are connected with each other through a water pump 4, and water of the filter body 1 is conveyed into the brine monitoring device; the brine monitoring device comprises a brine monitoring column I2 and a brine monitoring column II 3, and the brine monitoring column I2 and the brine monitoring column II 3 are connected through a flange plate. The filter body 1 is connected with the water pump 4 through a pipeline, and then is connected to the top of the first brine monitoring cylinder 2 through a pipeline to realize the function of conveying water.

Further, a water inlet pipe 14 is arranged at one side of the outside of the filter body 1, the inlet pipe 14 enters the brine to be purified, and a particle removal motor 5 is arranged at the other side of the filter body 1; a stirring motor 21 is arranged at the top of the first brine monitoring column 2; the surface of the second brine monitoring cylinder 3 is fixedly provided with a water outlet pipe 34, and filtered brine is monitored by a monitoring device and then discharged from the water outlet pipe 34.

As shown in fig. 2 and 3, a filter screen 12 and a reverse osmosis membrane group 11 are respectively installed in the filter body 1, the filter screen 12 separates and adsorbs particulate impurities, and the reverse osmosis membrane group 11 filters and discharges salt in the brine; the bottom of the filter body 1 is provided with the through groove 13, the inner wall and the outer wall of the filter body 1 are penetrated through by the through groove 13, the through groove 13 is arranged at one end of the filter screen 12 to be filtered, and particles can fall to the bottom of the filter screen 12 and then fall into the through groove 13 due to self-contained weight when the particle impurities are blocked.

Further, the first rotary vane 51 and the second rotary vane 52 are mounted on the output shaft of the particle removing motor 5, and the first rotary vane 51 and the second rotary vane 52 are both disposed inside the filter body 1, the first rotary vane 51 is disposed at one side of the reverse osmosis membrane group 11 after filtering the brine for stirring the filtered water, and since the filtering effect of the reverse osmosis membrane group 11 is reduced after long-term use, a small part of tiny impurities and the like are insufficiently filtered, and the first rotary vane 51 can mix them and discharge the mixed water; the second rotating blade 52 is arranged above the through groove 13 and is used for poking the turnover fan blade 9.

Still further, a shaft is installed on the inner wall of the through groove 13, the shaft is connected with the inner wall of the through groove 13 through a bearing, the bearing is connected with the through groove 13 to realize rotation, the bearing is fixedly provided with a turnover fan blade 9, a particle collecting box 6 is arranged below the turnover fan blade 9, a storage groove 61 is formed in the particle collecting box 6, the storage groove 61 is in radian and is matched with the through groove 13, and the particle collecting box 6 is installed at the bottom of the filter body 1 through a sealing gasket and a screw; impurity particles isolated by the filter screen 12 can fall onto the surface of the turning fan blade 9, and the turning fan blade 9 is stirred by the first rotating blade 51, so that the impurity particles on the surface of the turning fan blade fall into the storage groove 61.

As shown in fig. 4 and 5, the output shaft of the stirring motor 21 is inserted into the stirring gear one 22, the stirring gear one 22 is meshed with the stirring gear two 7, the stirring gears two 7 are four in number and uniformly distributed on the circumference of the stirring gear one 22, the stirring gear two 7 is inserted into the connecting shaft 71, and the connecting shaft 71 is also four. The stirring gear one 22 and the stirring gear two 7 are both disposed in the groove of the brine monitoring cylinder one 2, and the connecting shaft 71 is mounted in the groove by a bearing.

Further, a trapezoid stirring rod 73 and a stirring blade 72 are sequentially fixed on the connecting shaft 71, and the trapezoid stirring rod 73 and the stirring blade 72 are rotatably arranged in the filtered water flowing groove 32 and are used for stirring the filtered water flowing in the filtered water flowing groove 32; the water injection groove 31 is formed in the second brine monitoring cylinder 3, water conveyed by the water pump 4 enters the water injection groove 31, and filtered water flows through the groove 32 and is formed in the bottom of the water injection groove 31, and the number of the filtered water is four.

Still further, the inner wall of the filtering water flowing through groove 32 is provided with a monitor inserting hole 33, the monitor inserting hole 33 is the same as the outside of the second salt water monitoring cylinder 3 and is used for inserting the salt water concentration monitor 8, the four salt water concentration monitors 8 are inserted into different filtering water flowing through grooves 32 through the sealing gaskets, different positions of the filtering water flowing through can be monitored, and the average value is obtained, so that more accurate salt water concentration data is obtained, and tiny particles and the like float through the trapezoid stirring rod 73 and the stirring blade 72, so that the monitoring precision is facilitated. The monitor insertion hole 33 and the connection shaft 71 constitute a monitor mechanism.

The principle of operation of the filter with on-line brine monitoring is described in detail below.

As shown in fig. 1 to 5, first, four brine concentration monitors 8 are inserted into monitor insertion holes 33 in different filtered water flow channels 32, respectively, and the four brine concentration monitors 8 are installed at different positions to obtain accurate brine concentration values; then, the salt water to be purified is conveyed into the filter body 1 from the water inlet pipe 14, particle impurities are intercepted through the filter screen 12, part of the particle impurities fall onto the surface of the turnover fan blade 9 at the bottom of the salt water to be purified, the particle removal motor 5 is started to drive the rotary blade II 52 to rotate, the rotary blade II 52 contacts with the surface of the turnover fan blade 9 and stirs the rotary blade II to rotate, so that the particle impurities on the surface of the turnover fan blade 9 are collected into the storage groove 61, and then the particle impurities can be uniformly collected through the disassembly of the particle collection box 6 to prevent the particle impurities from affecting the use of the filter screen 12; the reverse osmosis membrane group 11 filters the brine to form filtered water, the filtered water is conveyed to the water injection groove 31 in the brine monitoring column II 3 through the water pump 4, the water flowing through the groove 32 is filled with the filtered water, and the water flowing through the groove 32 is continuously replaced when the filtered water is continuously conveyed, so that the filtered water can be updated in real time; the stirring motor 21 is started to enable the stirring gear I22 to be meshed with the stirring gear II 7, the connecting shaft 71 is driven to control the stirring blades 72 and the trapezoid stirring rod 73 to rotate in the filtering water flowing groove 32, the filtering water in the filtering water flowing groove is enabled to be mixed, the filtering water is monitored through the salt water concentration monitor 8, and finally the salt concentration of the filtering water is obtained by taking the average value of four values.

The foregoing utility model has been generally described in great detail, but it will be apparent to those skilled in the art that modifications and improvements can be made thereto. Accordingly, it is intended to cover modifications or improvements within the spirit of the inventive concepts.

Claims (6)

1. A filter with on-line brine monitoring, characterized by: the filter comprises a filter body and a brine monitoring device, wherein the filter body and the brine monitoring device are connected with each other through a water pump; the brine monitoring device consists of a first brine monitoring cylinder and a second brine monitoring cylinder, and the first brine monitoring cylinder is connected with the second brine monitoring cylinder through a flange plate; a water injection groove is formed in the second saline water monitoring cylinder, four filtered water flowing grooves are formed in the bottom of the water injection groove, and a monitoring mechanism is arranged in each filtered water flowing groove;

the monitoring mechanism comprises a monitor insertion hole and a connecting shaft, wherein the monitor insertion hole is formed in the inner wall of the filtered water flow trough, and a brine concentration monitor is inserted into the monitor insertion hole; a trapezoid stirring rod and a stirring blade are sequentially fixed on the connecting shaft;

the bottom of the filter body is provided with a through groove, the inner wall of the through groove is provided with a turnover fan blade, the bottom of the turnover fan blade is provided with a storage groove, and the storage groove is arranged in the particle collecting box.

2. A filter with on-line brine monitoring as in claim 1 wherein: the inside of filter body installs reverse osmosis membrane group and filter screen in proper order, the inlet tube is installed to outside one side of filter body, and the granule motor of getting rid of is installed to the opposite side of filter body.

3. A filter with on-line brine monitoring as claimed in claim 2, wherein: the output shaft of the particle removal motor is provided with a first rotating blade and a second rotating blade, and the first rotating blade and the second rotating blade are arranged inside the filter body.

4. A filter with on-line brine monitoring as in claim 1 wherein: and the top of the first salt water monitoring column body is provided with a stirring motor, and an output shaft of the stirring motor is connected with the first stirring gear in an inserting mode.

5. A filter with on-line brine monitoring as in claim 4 wherein: the stirring gear I is meshed with the stirring gear II, and the stirring gear II is spliced with the connecting shaft.

6. A filter with on-line brine monitoring as in claim 1 wherein: and a water outlet pipe is fixed on the surface of the second brine monitoring cylinder.