CN215387726U - Membrane cleaner apparatus for producing with high-efficient stirring function that mixes - Google Patents

Abstract

The utility model discloses a membrane cleaning agent production device with an efficient mixing and stirring function, which comprises a static shell and a fixed plate, wherein the top of the static shell is provided with a stirring shell, the inner wall of the top of the static shell is provided with a protective shell, the inside of the protective shell is provided with a motor through a rivet belt, the output end of the motor is provided with a rotating rod, the outer surface of the rotating rod is provided with a cutting tool bit, the outer surface of the rotating rod is provided with a stirring tool bit, and the inside of the static shell is provided with a macroporous sponge layer through a fixed bolt. According to the utility model, the stirring tool bit and the macroporous sponge layer are arranged on the static shell, the stirring tool bit stirs the interior of the membrane cleaning agent, so that bubbles deposited in the membrane cleaning agent rise to the top of the membrane cleaning agent, and when the membrane cleaning agent flows downwards through the holes in the top of the macroporous sponge layer under the action of gravity, the bubbles in the top of the membrane cleaning agent are separated at the top of the macroporous sponge layer, so that the removal of the bubbles in the membrane cleaning agent is completed.

Description

Membrane cleaner apparatus for producing with high-efficient stirring function that mixes

Technical Field

The utility model relates to the technical field of production of membrane cleaning agents, in particular to a membrane cleaning agent production device with an efficient mixing and stirring function.

Background

Along with the continuous development of modern society and the continuous improvement of economic level, people are also improving gradually to the utilization ratio and the rare degree of water resource, in order to improve the utilization ratio of water resource, just need to use water filtration equipment right, impurity and the pollution of aquatic are filtered, and current water filtration equipment often need use the membrane of permeating to hold back to the membrane top with the undissolved substance and the pollution of aquatic, and the membrane of permeating uses for a long time then can cause the sediment of membrane top impurity, and then influence the membrane filtration effect of permeating, just need use the membrane cleaner to wash the membrane of permeating this moment, get rid of the undissolved substance and the impurity at membrane top of permeating, make the membrane of permeating resume the permeability.

The membrane cleaning agent production device in the prior art has the following defects:

1. the existing production device for the membrane cleaning agent is lack of a foam removing part, so that bubbles existing on the surface of the membrane cleaning agent cannot be treated in the production process of the membrane cleaning agent, and the bottling effect of the membrane cleaning agent is influenced.

2. The existing production device for the membrane cleaning agent is lack of a temperature control component, so that the temperature of the membrane cleaning agent cannot be controlled in the production process of the membrane cleaning agent, and the application range of the device is further influenced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a membrane cleaning agent production device with an efficient mixing and stirring function, so as to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides a membrane cleaner apparatus for producing with high-efficient stirring function that mixes, includes static shell and fixed plate, the stirring shell is installed at the top of static shell, the protective housing is installed to the top inner wall of static shell, the motor is installed through the rivet area in the inside of protective housing, the bull stick is installed to the output of motor, and the top of bull stick extends to the inside of stirring shell, the surface mounting of bull stick has the cutting tool bit, the surface mounting of bull stick has the stirring tool bit, and the stirring tool bit is located the top of cutting tool bit, the top of static shell and the bottom of stirring shell all run through and have seted up a plurality of weeping holes, the macropore sponge layer is installed through the gim peg in the inside of static shell.

Preferably, four groups of supporting columns are installed at the bottom of the static casing, a fixing plate is installed at the bottom of each supporting column, and four groups of fixing holes are formed in the fixing plate in a penetrating mode.

Preferably, the front surface of the static shell is provided with a control screen, the bottom of the static shell is provided with an electric shutoff valve through a connecting pipe, the electric shutoff valve is electrically connected with the control screen, and the bottom end of the electric shutoff valve is provided with an output pipe.

Preferably, the pressure sensor is installed through the rivet area in the inside of static shell, and pressure sensor is located the top on macropore sponge layer, and pressure sensor and control panel electric connection, the internally mounted of static shell has temperature sensor, and temperature sensor is located one side of pressure sensor, and temperature sensor and control panel electric connection.

Preferably, the inner wall of the stationary shell is internally provided with an electric heating tube in a surrounding manner, and the electric heating tube is electrically connected with the control screen.

Preferably, a pressure relief valve is arranged at the top of the stirring shell.

Preferably, the honeycomb duct is installed at the top of stirring shell, and the honeycomb duct is located one side of relief valve, the feeder hopper is installed on the top of honeycomb duct, the top cap is installed through opening and shutting the page or leaf in the top of feeder hopper, the electro-magnet is installed to the inboard of top cap inlaying, and electro-magnet and control panel electric connection.

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

1. according to the membrane cleaning agent, the stirring tool bit and the macroporous sponge layer are arranged, the stirring tool bit rotates under the driving of the rotating rod, the outer surface of the stirring tool bit stirs the interior of the membrane cleaning agent, so that bubbles deposited in the membrane cleaning agent rise to the top of the membrane cleaning agent, primary separation of the bubbles is completed, when the membrane cleaning agent falls to the top of the macroporous sponge layer under the action of gravity, the bubbles on the top of the membrane cleaning agent are separated on the top of the macroporous sponge layer through downward seepage through holes in the top of the macroporous sponge layer under the action of gravity, and the bubbles in the membrane cleaning agent are removed.

2. The control screen, the temperature sensor and the electric heating tube are arranged, the sensing interval of the temperature sensor is set through the control screen before the device is used, when the temperature in the device is too high, an electric signal is conducted into the control screen to power off the electric heating tube, when the temperature in the device is too low, the electric signal is conducted into the control screen to power on the electric heating tube, after the electric heating tube is powered on, a resistance wire in the electric heating tube generates a large amount of heat through an electric heating effect, and the heat is conducted into the static shell through the inner wall of the static shell, so that the regulation and control of the temperature in the static shell are completed.

Drawings

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

FIG. 2 is a front view of the present invention;

FIG. 3 is a front view of the present invention in cross-section;

fig. 4 is a bottom sectional partial structural schematic view of the top cover of the present invention.

In the figure: 1. a stationary housing; 2. a stirring shell; 3. a protective shell; 4. an electric motor; 5. a rotating rod; 6. a cutting bit; 7. a stirring cutter head; 8. a weep hole; 9. a macroporous sponge layer; 10. a support pillar; 11. a fixing plate; 12. a control screen; 13. an electric shut-off valve; 14. an output pipe; 15. a pressure sensor; 16. a temperature sensor; 17. an electric heating tube; 18. a pressure relief valve; 19. a flow guide pipe; 20. a feed hopper; 21. a top cover; 22. an electromagnet.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1 to 4, an embodiment of the present invention includes: a membrane cleaning agent production device with high-efficiency mixing and stirring functions comprises a static shell 1 and a fixed plate 11, wherein the top of the static shell 1 is provided with a stirring shell 2, the static shell 1 is the stirring shell 2 arranged on the outer surface and inside, a protective shell 3, a leakage hole 8, a large-pore sponge layer 9, a support column 10, a control screen 12, an electric shutoff valve 13, a pressure sensor 15, a temperature sensor 16 and an electric heating tube 17 provide fixed points, meanwhile, a containing space is provided for a membrane cleaning agent flowing into the static shell through the leakage hole 8, the stirring shell 2 is the leakage hole 8 arranged on the outer surface and inside, a pressure relief valve 18 and a flow guide pipe 19 provide fixed points, meanwhile, a short containing space is provided for the membrane cleaning agent entering the static shell through the flow guide pipe 19, the protective shell 3 is arranged on the inner wall of the top of the static shell 1 and provides a fixed point for a motor 4 arranged inside, and simultaneously, substances such as external dust and water are prevented from entering the motor 4 to cause short circuit, the motor 4 is arranged in the protective shell 3 through a rivet belt, after being electrified, the electric energy is transferred into mechanical energy through the electromagnetic effect, the rotational force is output to the inside of the rotating rod 5, the rotating rod 5 is arranged at the output end of the motor 4, the top end of the rotating rod 5 extends to the inside of the stirring shell 2, the rotational force output by the motor 4 is converted into kinetic energy to drive the cutting tool bit 6 and the stirring tool bit 7 which are arranged on the outer surfaces of the cutting tool bit 6 and the stirring tool bit 7 to rotate, the cutting tool bit 6 is driven by the rotating rod 5 to rotate, solid insoluble substances and residues accumulated in the membrane cleaning agent on the top of the leakage hole 8 are cut into smaller particles to be dissolved into the membrane cleaning agent solution again, the stirring tool bit 7 is arranged on the outer surface of the rotating rod 5, the stirring tool bit 7 is positioned above the cutting tool bit 6, and the stirring tool bit 7 is driven by the rotating rod 5 to rotate, its surface stirs the inside of membrane cleaner, make the inside bubble of deposit at membrane cleaner rise to the top of membrane cleaner, accomplish the first separation of bubble, the top of the shell 1 of stewing and the bottom of stirring shell 2 all run through and have seted up a plurality of seepage holes 8, the top of the shell 1 of intercommunication stewing and the bottom of stirring shell 2, make the membrane cleaner through the stirring can be under the effect of gravity, the seepage gets into the inside of the shell 1 of stewing, the inside of the shell 1 of stewing installs macroporous sponge layer 9 through the gim peg, when the membrane cleaner drops to the top of macroporous sponge layer 9 under the action of gravity, the hole downward seepage flow at macroporous sponge layer 9 top under the action of gravity, separate the bubble at macroporous sponge layer 9's top at membrane cleaner top, accomplish getting rid of bubble in the membrane cleaner.

Further, four groups of support columns 10 are installed to the bottom of shell 1 that stews, when the holding power conducts to its inside, the bottom of resting shell 1 is connected to support column 10, for the whole support that provides of device, fixed plate 11 is installed to the bottom of support column 10, and fixed plate 11's inside runs through and has seted up four groups of fixed orificess, when fixed plate 11 is placed at the ground top, the whole ground production pressure to ground via fixed plate 11 of device, ground produces the holding power to the bottom of fixed plate 11 this moment, for the whole support that provides of device, when the device needs to be fixed, through inserting external bolt the inside of the fixed orificess of running through of fixed plate 11 inside, later insert the top on ground with external bolt, accomplish the holistic fixed of device.

Further, the front of the standing shell 1 is provided with a control screen 12 which is respectively electrically connected with the electric shutoff valve 13, the pressure sensor 15, the temperature sensor 16, the electric heating tube 17 and the electromagnet 22 to control the on-off of the electric shutoff valve 13, convert the electric signal transmitted to the inside of the pressure sensor 15 into a digital signal to be displayed, facilitate the user to check the pressure inside the device, control the on-off of the current inside the electric heating tube 17 after receiving the electric signal of the temperature sensor 16, simultaneously control the on-off of the current inside the electromagnet 22 according to the opening and closing requirements of the feed hopper 20, the bottom of the standing shell 1 is provided with the electric shutoff valve 13 through a connecting pipe, the electric shutoff valve 13 is electrically connected with the control screen 12, the electric shutoff valve 13 is in a closed state in a normal state, when the membrane cleaning agent needs to be led out, the electric signal is transmitted to the inside the electric shutoff valve 13 through the control screen 12, the electric shutoff valve 13 is opened, so that the membrane cleaning agent which is subjected to bubble elimination by the macroporous sponge layer 9 can flow into the internal part of the output pipe 14 through the electric shutoff valve 13 under the influence of gravity, the output pipe 14 is installed at the bottom end of the electric shutoff valve 13, the device is connected with the external storage device through the threads arranged at the bottom of the output pipe 14 before the device is used, and the membrane cleaning agent which flows out through the output pipe 14 can flow into the internal part of the external storage device under the action of gravity to finish the output of the membrane cleaning agent.

Further, a pressure sensor 15 is installed in the standing shell 1 through a rivet belt, the pressure sensor 15 is located above the macroporous sponge layer 9, the pressure sensor 15 is electrically connected with the control screen 12, the pressure in the standing shell 1 is detected after the power is on, when the pressure in the device is too high, an electric signal is transmitted to the inside of the control screen 12 and is displayed by the control screen 12 to remind a worker to relieve the pressure of the device, a temperature sensor 16 is installed in the standing shell 1, the temperature sensor 16 is located on one side of the pressure sensor 15 and is electrically connected with the control screen 12, a sensing interval of the temperature sensor 16 is set through the control screen 12 before the device is used, when the temperature in the device is too high, the electric signal is transmitted to the inside of the control screen 12 to power off the electric heating pipe 17, and when the temperature in the device is too low, the electric signal is transmitted to the inside of the control screen 12, the electric heating tube 17 is energized.

Further, an electric heating tube 17 is installed inside the inner wall of the standing shell 1 in a surrounding mode, the electric heating tube 17 is electrically connected with the control screen 12, after the electric heating tube 17 is powered on, resistance wires inside the electric heating tube generate a large amount of heat through an electric heating effect, and the heat is conducted to the inside of the standing shell 1 through the inner wall of the standing shell 1, so that the temperature inside the standing shell 1 is improved.

Further, a pressure release valve 18 is installed at the top of the stirring shell 2, when the device needs pressure release, the top of the pressure release valve 18 is pressed through external force, so that the exhaust holes in the pressure release valve 18 are communicated, air in the device is discharged, the pressure in the device is reduced, and the safety of the device is guaranteed.

Furthermore, a guide pipe 19 is installed at the top of the stirring shell 2, the guide pipe 19 is located at one side of the pressure release valve 18 and connects the bottom of the feed hopper 20 with the inside of the stirring shell 2, so that a membrane cleaning agent inside the feed hopper 20 can enter the inside of the stirring shell 2 through the guide pipe 19 under the action of gravity, the feed hopper 20 is installed at the top end of the guide pipe 19, when the top cover 21 is opened, the membrane cleaning agent is injected into the inside of the feed hopper 20, the top cover 21 is installed at the top end of the feed hopper 20 through an opening and closing leaf, the top cover 20 is closed in a normal state to shield the top of the feed hopper 20 and prevent external dust pollutants from entering the inside of the feed hopper 20, an electromagnet 22 is installed at the inner side of the top cover 21 in an embedded manner, the electromagnet 22 is electrically connected with the control screen 12, after the electromagnet 22 is electrified to generate magnetic force to attract the top of the feed hopper 20, so that the top cover 21 is fixed at the top of the feed hopper 20, when the feed hopper 20 needs to be opened, the electromagnet 22 is powered off through the control panel 12, and then the top cover 21 is moved through external force to drive the opening and closing leaf to rotate so as to separate the top cover 21 from the feed hopper 20.

The working principle is as follows: firstly, an external bolt is inserted into the inside of a fixing hole which is arranged in a penetrating way in a fixing plate 11, then the external bolt is inserted into the top of the ground to finish the whole fixing of the device, then the device is connected with an external storage device through a thread arranged at the bottom of an output pipe 14, a power supply is connected, an electromagnet 22 is powered off through a control screen 12, then a top cover 21 is moved through external force to drive an opening and closing leaf to rotate so as to finish the separation of the top cover 21 and a feed hopper 20, when the top cover 21 is opened, a membrane cleaning agent is injected into the inside of the feed hopper 20, a guide pipe 19 is connected with the bottom of the feed hopper 20 and the inside of a stirring shell 2, the membrane cleaning agent in the feed hopper 20 can enter the inside of the stirring shell 2 through the guide pipe 19 under the action of gravity, meanwhile, after the motor 4 is powered on, electric energy is transferred into mechanical energy through an electromagnetic effect, the rotating force is output to the inside of a rotating rod 5, and the rotating rod 5 converts the rotating force output by the motor 4 into kinetic energy, the cutting tool bit 6 and the stirring tool bit 7 which are arranged on the outer surface of the cutting tool bit 6 are driven by the rotating rod 5 to rotate, solid insoluble substances and residues accumulated in the membrane cleaning agent on the top of the leakage hole 8 are cut to be smaller particles and are dissolved into the membrane cleaning agent solution again, the stirring tool bit 7 is driven by the rotating rod 5 to rotate, the inner part of the membrane cleaning agent is stirred by the outer surface of the stirring tool bit, bubbles deposited in the membrane cleaning agent rise to the top of the membrane cleaning agent to complete primary separation of the bubbles, then the membrane cleaning agent leaks into the static shell 1 under the action of gravity, when the membrane cleaning agent falls to the top of the macroporous sponge layer 9 under the action of gravity, the bubbles on the top of the membrane cleaning agent downwards seep through holes on the top of the macroporous sponge layer 9 under the action of gravity, and are separated on the top of the macroporous sponge layer 9, and finally, conducting an electric signal to the interior of the electric shutoff valve 13 through the control screen 12 to open the electric shutoff valve 13, so that the membrane cleaning agent with bubbles eliminated by the macroporous sponge layer 9 can be influenced by gravity and flows into the interior of the output pipe 14 through the electric shutoff valve 13, and the membrane cleaning agent flowing out of the output pipe 14 flows into the interior of the external storage device under the action of gravity to finish the output of the membrane cleaning agent.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (7)

1. The utility model provides a membrane cleaner apparatus for producing with high-efficient stirring function that mixes, includes stationary casing (1) and fixed plate (11), its characterized in that: stirring shell (2) are installed at the top of quiet shell (1), protective housing (3) are installed to the top inner wall of quiet shell (1), motor (4) are installed through the rivet area in the inside of protective housing (3), bull stick (5) are installed to the output of motor (4), and the top of bull stick (5) extends to the inside of stirring shell (2), the surface mounting of bull stick (5) has cutting tool bit (6), the surface mounting of bull stick (5) has stirring tool bit (7), and stirring tool bit (7) are located the top of cutting tool bit (6), the top of quiet shell (1) and the bottom of stirring shell (2) all run through and have seted up a plurality of seepage holes (8), macroporous sponge layer (9) are installed through the gim peg in the inside of quiet shell (1).

2. The membrane cleaning agent production device with the efficient mixing and stirring function as claimed in claim 1, wherein: four groups of supporting columns (10) are installed at the bottom of the static casing (1), a fixing plate (11) is installed at the bottom of each supporting column (10), and four groups of fixing holes are formed in the fixing plate (11) in a penetrating mode.

3. The membrane cleaning agent production device with the efficient mixing and stirring function as claimed in claim 1, wherein: the front side of the static shell (1) is provided with a control screen (12), the bottom of the static shell (1) is provided with an electric shutoff valve (13) through a connecting pipe, the electric shutoff valve (13) is electrically connected with the control screen (12), and the bottom end of the electric shutoff valve (13) is provided with an output pipe (14).

4. The membrane cleaning agent production device with the efficient mixing and stirring function as claimed in claim 1, wherein: pressure sensor (15) are installed through the rivet area in the inside of static shell (1), and pressure sensor (15) are located the top of macropore sponge layer (9), and pressure sensor (15) and control panel (12) electric connection, the internally mounted of static shell (1) has temperature sensor (16), and temperature sensor (16) are located one side of pressure sensor (15), and temperature sensor (16) and control panel (12) electric connection.

5. The membrane cleaning agent production device with the efficient mixing and stirring function as claimed in claim 1, wherein: an electric heating tube (17) is installed in the inner wall of the static shell (1) in a surrounding mode, and the electric heating tube (17) is electrically connected with the control screen (12).

6. The membrane cleaning agent production device with the efficient mixing and stirring function as claimed in claim 1, wherein: and a pressure release valve (18) is arranged at the top of the stirring shell (2).

7. The membrane cleaning agent production device with the efficient mixing and stirring function as claimed in claim 1, wherein: honeycomb duct (19) are installed at the top of stirring shell (2), and honeycomb duct (19) are located one side of relief valve (18), feeder hopper (20) are installed on the top of honeycomb duct (19), top cap (21) are installed through opening the hinge on the top of feeder hopper (20), electromagnet (22) are installed to the inboard of top cap (21) is inlayed, and electromagnet (22) and control panel (12) electric connection.

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