CN117380638A - Self-cleaning type automatic liquid level control water washing device - Google Patents

Abstract

The invention relates to the technical field of washing devices, in particular to a self-cleaning type automatic liquid level control washing device. When the liquid level in the washing cylinder is inclined, the liquid level detection device can transmit wrong liquid level information, so that the technical problem that the contact time between the front and back passing gas and water is different is solved. The novel water supply device comprises a base, a water washing barrel is fixedly connected with the base, a water pipe is fixedly connected and communicated with the water washing barrel, an air inlet pipe is fixedly connected with the water pipe, an air outlet pipe is fixedly connected and communicated with the water washing barrel, an annular array fixing shaft is fixedly connected in the water washing barrel, and the annular array fixing shaft is all slidably connected with a buoy. According to the invention, the liquid level of water in the washing barrel is detected through the annular array of the floats, so that the phenomenon that the floats are easily touched by mistake when the water washing barrel is impacted to incline due to single float position is avoided, and redundant water drainage and water injection are carried out in the washing barrel.

Description

Self-cleaning type automatic liquid level control water washing device

Technical Field

The invention relates to the technical field of washing devices, in particular to a self-cleaning type automatic liquid level control washing device.

Background

Before the specific gas concentration content of the sampled gas is detected, the gas detection analysis needs to carry out washing pretreatment on the sampled gas so as to remove impurities and dust in the sampled gas, but in the gas washing process, the stability of the liquid level height needs to be ensured, most of the liquid level detection devices of the existing automatic liquid level control device are fixed in position and are used for independent detection, when the washing cylinder is impacted by an external device and vibration is conducted, the liquid level in the washing cylinder is easy to incline, and error liquid level information is transmitted to the liquid level detection device, so that the liquid level control is deviated, the contact time between the front-back passing gas and water is different, the gas washing inaccuracy is caused, and meanwhile, the bubbles generated by the sample gas cannot be reprocessed by the existing washing device after the gas is injected into the washing cylinder, so that the accuracy and uniformity of the sample gas washing are further increased.

Disclosure of Invention

In order to overcome the defects in the background art, the invention provides a self-cleaning automatic liquid level control water washing device.

The technical proposal is as follows: the utility model provides an automatic liquid level control washing device of automatically cleaning, includes the base, base fixedly connected with wash bowl, wash bowl fixedly connected with raceway and intercommunication, raceway fixedly connected with intake pipe, wash bowl fixedly connected with and intercommunication have the outlet duct, wash bowl fixedly connected with outlet pipe, fixedly connected with annular array's fixed axle in the wash bowl, annular array the equal sliding connection of fixed axle has cursory, cursory fixedly connected with mirror image distributed's first extrusion piece, cursory with wash bowl sliding fit, mirror image distributed the first extrusion piece is located wash bowl outside, wash bowl sliding connection has mirror image distributed and annular array's second extrusion piece, first extrusion piece with adjacent second extrusion piece cooperation, the raceway with equal sliding connection has linear array's closing plate in the outlet pipe, linear array the closing plate with adjacent second extrusion piece fixed connection, the outlet pipe with be provided with first reset spring between water raceway and the adjacent second extrusion piece, the intake pipe is provided with reset spring, breather pipe fixedly connected with in the breather pipe.

More preferably, a gap is left between adjacent sealing plates, and the gap is used for circulating water.

More preferably, the bottom of the vent pipe is rotationally connected with a rotary drum, a first fan blade of an annular array is fixedly connected in the rotary drum, the rotary drum is fixedly connected with and communicated with an annular array air outlet sleeve, and the annular array air outlet sleeve is positioned below the first fan blade.

More preferably, the pressure accumulating plate is slidably connected in the rotary drum, and a second return spring is arranged between the rotary drum and the pressure accumulating plate.

More preferably, the breather pipe is rotationally connected with a first rotating cylinder of a linear array, the first rotating cylinders of the linear array are all fixedly connected with baffle plates of an annular array, the first rotating cylinders of the linear array are all fixedly connected with second fan blades of the annular array, and the baffle plates are fixedly connected with drainage blocks distributed in a mirror image mode.

More preferably, the baffle plate is a transversely placed V-shaped plate, the sharp point of the baffle plate faces in the same direction as the rotation direction of the first rotating cylinder, and the drainage block is positioned on the outer side face of the baffle plate.

More preferably, the breather pipe is slidably connected with vibration rods which are distributed in an annular mode and are in linear arrays, a third reset spring is arranged between the vibration rods and the breather pipe, a first jacking block which is in an annular array is fixedly connected in the first rotating cylinder, and the first jacking block which is in an annular array is matched with the vibration rods.

More preferably, the baffle plates positioned in the same vertical direction are fixedly connected with a cleaning rod together, and the cleaning rod is used for cleaning the inner wall of the washing cylinder.

More preferably, the cleaning frame with the annular array is rotatably connected in the washing cylinder, the annular array is provided with torsion springs between the cleaning frame and the washing cylinder, the cleaning frame is fixedly connected with a fixed outer plate, the fixed outer plate is slidably connected with a push plate, a linear array fourth reset spring is arranged between the push plate and the adjacent fixed outer plate, and the push plate is matched with the cleaning rod.

More preferably, the washing section of thick bamboo fixedly connected with annular array's second kicking block, the breather pipe rotates and is connected with the second and rotates a section of thick bamboo, the second rotates a section of thick bamboo internal fixation and is connected with annular array's third flabellum, the second rotates a section of thick bamboo fixedly connected with mount, mount sliding connection has the push rod, push rod fixedly connected with gets the material basket, the mount with be provided with the extension spring between the material basket, annular array the second kicking block all with the push rod cooperation.

The beneficial effects of the invention are as follows:

1. the liquid level of water in the washing barrel is detected through the cursory of the annular array, the cursory position is single, when the washing barrel is impacted and the inner liquid level is inclined, the cursory is easy to be mistakenly touched, and redundant drainage and water injection are carried out in the washing barrel.

2. The gas is accumulated through the pressure accumulating plate, so that the gas pressure of the rotary drum is increased, the gas is pushed by the high pressure of the gas to uniformly enter the annular array gas outlet sleeve, and meanwhile, the annular array gas outlet sleeve rotates in the water washing drum to give out gas, so that the uniformity of gas exhaust is further improved, and the gas water washing precision is improved.

3. The air bubbles formed by the water washing gas in the water washing cylinder are stirred through the annular array baffle plates, meanwhile, the baffle plates rotate to guide water flow to the upper side and the lower side to generate opposite impact, the air bubbles are broken by the stirring force and opposite impact force of the baffle plates, the contact area between the air bubbles and the water is increased, and the gas washing precision is improved.

4. The vibration rod is extruded by the first ejector block, so that the vibration rod impacts the first rotating cylinder to generate vibration force when being reset, impurities carried in gas are prevented from adhering to the surface of the baffle plate, the flow guiding effect of the baffle plate is reduced, and meanwhile, the vibration force of the baffle plate further strengthens the stirring bubble cracking effect.

5. The cleaning rod pushes the cleaning frame to rotate the self-cleaning impurity on the inner wall of the water washing cylinder around the float, so that the float is ensured to slide up and down quickly and stably.

6. Through the extrusion and the reset of push rod and second kicking block, make get the material basket at liquid level up-and-down circulation motion, will float the impurity pocket internal portion at the surface of water, avoid the liquid level to float too much impurity in the washing section of thick bamboo, lead to the gaseous difficult discharge of washing.

Drawings

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

FIG. 2 is a schematic cross-sectional view of a perspective structure of a cartridge according to the present invention;

fig. 3 is a schematic cross-sectional view of a three-dimensional structure of a water pipe according to the present invention;

FIG. 4 is a schematic cross-sectional view of the perspective of the drum of the present invention;

FIG. 5 is a schematic perspective view of a first rotary drum and a cleaning frame according to the present invention;

FIG. 6 is a schematic perspective view of a first rotary drum, a second rotary drum and a rotary drum according to the present invention;

FIG. 7 is a schematic cross-sectional view of a vent pipe of the present invention;

FIG. 8 is a schematic perspective view of a cleaning frame according to the present invention;

FIG. 9 is a schematic cross-sectional view of a solid structure of a stationary outer plate of the present invention;

FIG. 10 is a schematic perspective view of a second top block and a fixing frame according to the present invention;

FIG. 11 is a schematic perspective view of the push rod and take-out basket of the present invention;

reference numerals in the figures: 101-base, 102-washing drum, 103-water delivery pipe, 104-air inlet pipe, 105-air outlet pipe, 106-water outlet pipe, 107-fixed shaft, 108-float, 109-first extrusion block, 110-second extrusion block, 111-first reset spring, 112-sealing plate, 113-vent pipe, 201-drum, 202-first fan blade, 203-air outlet sleeve, 204-hold-down plate, 205-second reset spring, 301-first rotating drum, 302-baffle, 303-second fan blade, 304-drainage block, 401-vibration rod, 402-third reset spring, 403-first top block, 501-cleaning rod, 601-cleaning rack, 602-torsion spring, 603-fixed outer plate, 604-push plate, 605-fourth reset spring, 701-second top block, 702-second rotating drum, 703-third fan blade, 704-fixed frame, 705-push rod, 706-material taking basket, 707-tension spring.

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

Example 1: 1-3, including a base 101, the base 101 is fixedly connected with a washing barrel 102, the washing barrel 102 is formed by splicing a main barrel in the middle and three auxiliary barrels in an annular array, the top of the washing barrel 102 is fixedly connected with a water pipe 103, the top of the washing barrel 102 is fixedly connected with an air inlet pipe 104 positioned in the water pipe 103, the air inlet pipe 104 is communicated with an external air extractor, the washing barrel 102 is fixedly connected with an air outlet pipe 105, the bottom of the washing barrel 102 is fixedly connected with an air outlet pipe 106, three fixed shafts 107 in the annular array are fixedly connected in the washing barrel 102, the fixed shafts 107 are positioned in the auxiliary barrels of the washing barrel 102, the three fixed shafts 107 in the annular array are all connected with a float 108 in a sliding manner, the float 108 is composed of a floating body and a frame body, the frame body of the float 108 is fixedly connected with two first extrusion blocks 109 which are distributed in a mirror image up and down, the first extrusion block 109 is a wedge block, the frame body of the float 108 is in sliding fit with the washing barrel 102, two first extrusion blocks 109 distributed in a mirror image mode are positioned outside the washing barrel 102, the washing barrel 102 is in sliding connection with six second extrusion blocks 110 distributed in a mirror image mode and in an annular array, the second extrusion blocks 110 are wedge blocks attached to the first extrusion blocks 109, the first extrusion blocks 109 are matched with the adjacent second extrusion blocks 110, the first extrusion blocks 109 extrude the adjacent second extrusion blocks 110, the second extrusion blocks 110 are outwards slid along the washing barrel 102 by the extrusion force of the first extrusion blocks 109, the water pipe 103 and the water outlet pipe 106 are respectively and slidably connected with three sealing plates 112 in a linear array, gaps are reserved between the two adjacent sealing plates 112, water can be conveniently injected into the washing barrel 102 through the gaps, the six sealing plates 112 of the linear array are fixedly connected with the adjacent second extrusion blocks 110, the second extrusion blocks 110 slide outwards along the water washing cylinder 102 to drive the adjacent sealing plates 112 to slide outwards along the water conveying pipe 103 or the water outlet pipe 106, and then the sealing plates 112 are relieved from blocking the water conveying pipe 103 or the water outlet pipe 106, first reset springs 111 are arranged between the water conveying pipe 103 and the water outlet pipe 106 and the adjacent second extrusion blocks 110, the first reset springs 111 are used for resetting the sealing plates 112, so that the sealing plates 112 block the water conveying pipe 103 or the water outlet pipe 106, a ventilation pipe 113 is fixedly connected in the base 101, the ventilation pipe 113 is communicated with the air inlet pipe 104, the liquid level of water in the water washing cylinder 102 is detected simultaneously through the three floats 108 of the annular array, the phenomenon that the position of the floats 108 is single, when the water washing cylinder 102 is impacted to incline due to the fact that the liquid level inside is impacted is avoided, the floats 108 are extremely easy to be mistakenly touched, redundant drainage and water injection are conducted in the water washing cylinder 102, and the accuracy of gas washing is affected.

As shown in fig. 2 and fig. 4, the bottom of the breather pipe 113 is rotationally connected with a drum 201, a first fan blade 202 of an annular array is fixedly connected in the drum 201, five air outlet sleeves 203 of the annular array are fixedly connected and communicated with the drum 201, the five air outlet sleeves 203 of the annular array are all located below the first fan blade 202, the first fan blade 202 rotates in contact with gas, the first fan blade 202 rotates to drive the five air outlet sleeves 203 of the annular array to rotationally and air out through the drum 201, the uniformity of air out is increased, the drum 201 is slidably connected with an accumulator plate 204 located below the first fan blade 202, the accumulator plate 204 is disc-shaped, the air in the drum 201 is conveniently sealed, a second reset spring 205 is arranged between the drum 201 and the accumulator plate 204, the air is accumulated through the accumulator plate 204, the air pressure in the drum 201 is increased, the air is pushed to evenly enter the five air outlet sleeves 203 of the annular array through the high pressure of the air, and meanwhile the five air outlet sleeves 203 of the annular array rotate in the water washing drum, the uniformity of air out is further increased, and the air washing precision is improved.

When gas analysis is required, the water drum 102 is anhydrous, the three floats 108 in the annular array are dragged downwards by gravity, at this time, the three first extrusion blocks 109 and the adjacent second extrusion blocks 110 in the annular array below the water drum 102 are in a separated state, the water outlet pipe 106 is blocked by the three sealing plates 112 in the linear array, the three first extrusion blocks 109 and the adjacent second extrusion blocks 110 above the water drum 102 are in a compressed state, at this time, the first return springs 111 are in a compressed state, the three sealing plates 112 in the linear array in the water drum 103 do not block the water drum 103, at this time, water is injected into the water drum 102 through the water drum 103, the liquid level of the water in the water drum 102 is gradually increased, and the three floats 108 in the annular array are synchronously driven to slide upwards along the adjacent fixed shafts 107 until the first extrusion blocks 109 and the adjacent second extrusion blocks 110 above the water drum 102 are in a fitting state, the first return springs 111 reset the sealing plates 112 above the water drum 102 to block the water drum 103, and the water drum 102 reaches a designated position.

When the liquid level in the water washing drum 102 reaches a designated position, an external air extractor is started to extract air into the air inlet pipe 104, the air enters the air pipe 113 along the air inlet pipe 104, the air moves downwards in the air pipe 113 until the air enters the drum 201, and as the air accumulating plate 204 is used for blocking the drum 201, the air pressure in the drum 201 is gradually increased along with the extraction of the air extractor, the air pressure is increased to push the accumulating plate 204 to slide downwards along the drum 201, and meanwhile, the second reset spring 205 is compressed, when the accumulating plate 204 slides downwards along the drum 201 until the five air outlet sleeves 203 of the annular array are opened, the high-pressure air in the air drum 201 uniformly enters the five air outlet sleeves 203 of the annular array through the pressure pushing of the air outlet sleeves 203, and the air is accumulated through the accumulating plate 204, so that the air pressure of the drum 201 is increased, the air is uniformly pushed into the five air outlet sleeves 203 of the annular array through the high pressure of the air, the air is prevented from being discharged unevenly, the contact area between the air and the water is different, and the precision of gas water washing is reduced.

When the pressure accumulating plate 204 slides downwards along the drum 201 until the five air outlet sleeves 203 are opened, air flows in the drum 201 at this time, the air pushes the first fan blades 202 of the annular array, the first fan blades 202 of the annular array are pushed by the air to start rotating, the first fan blades 202 rotate to drive the drum 201 and the five air outlet sleeves 203 of the annular array to synchronously rotate, so that the five air outlet sleeves 203 of the annular array rotate to outlet air in the water washing drum 102, the uniformity of air discharge is further improved, the air washing precision is improved, and then the air after water washing enters the next step through the air outlet pipe 105.

In the water washing process, due to different air humidity, the extracted air humidity can carry the water in the water washing barrel 102 to be discharged after water washing, so that the liquid level in the water washing barrel 102 is reduced, when the extracted air humidity is high, part of the water in the air is dissolved in the water washing barrel 102, so that the liquid level in the water washing barrel 102 is raised, the liquid level in the water washing barrel 102 is unstable, the time length of the water washing of the air flowing back and forth is changed, so that the air washing is uneven, when the liquid level in the water washing barrel 102 is lowered, three floats 108 in an annular array are uniformly lowered at the moment, the first extrusion blocks 109 above the floats 108 are lowered to synchronously slide downwards, the first extrusion blocks 109 slide downwards to extrude adjacent second extrusion blocks 110, the second extrusion blocks 110 are extruded by the adjacent first extrusion blocks 109 to slide outwards along the water washing barrel 102, at this time, the first reset spring 111 is compressed, the first extrusion block 109 extrudes the adjacent second extrusion block 110 to slide outwards along the water drum 102 and drives the adjacent sealing plate 112 to slide outwards along the water drum 103, the sealing plate 112 slides outwards along the water drum 103 to release the blocking of the water drum 103, at this time, the blocking of the water drum 103 is released by the three sealing plates 112 of the linear array, the water drum 103 continues to fill water into the water drum 102, the liquid level of water in the water drum 102 is automatically increased, the liquid level of water in the water drum 102 is stabilized to an initial state, then the float 108 drives the three first extrusion blocks 109 of the upper annular array to reset, the first reset spring 111 resets, drives the three sealing plates 112 of the linear array to block the water drum 103 again, the liquid level of water in the water drum 102 is detected by the float 108, water filling and draining are automatically adjusted, the liquid level of water in the water drum 102 is stabilized, ensure the uniformity of gas water washing.

When the water washing drum 102 is subjected to vibration and impact, vibration force drives the liquid level of water in the water washing drum 102 to incline, at the moment, the total amount of water in the water washing drum 102 is not changed, but the water level is transiently changed, at the moment, the water level inclines to drive three floats 108 of the annular array to respectively ascend and descend, the floats 108 ascend and extrude adjacent second extrusion blocks 110 through the first extrusion blocks 109 below to release the blocking of the corresponding sealing plates 112 to the water outlet pipe 106, the first extrusion blocks 109 below are driven to be separated from the adjacent second extrusion blocks 110 by the descending of the floats 108, the corresponding sealing plates 112 still block the water outlet pipe 106, redundant water injection and drainage to the water washing drum 102 are avoided, the liquid level in the water washing drum 102 is ascended and descended, meanwhile, the liquid level of water in the water washing drum 102 is detected through the three floats 108 of the annular array, when the outside impacts the water washing drum 102 to incline, the position of the liquid level inclines to drive the floats 108 to change, the redundant water drainage and the water injection to be carried out in the water washing drum 102 are avoided, and the height in the water washing drum 102 is further reduced or the liquid level 102 is increased.

Example 2: on the basis of embodiment 1, as shown in fig. 5-7, the breather pipe 113 is rotationally connected with three first rotating cylinders 301 in a linear array, the three first rotating cylinders 301 in the linear array are fixedly connected with four baffle plates 302 in an annular array, the baffle plates 302 are transversely arranged V-shaped plates, the sharp points of the baffle plates 302 face in the same direction as the rotating direction of the first rotating cylinders 301, the baffle plates 302 rotate to flow water in the water washing cylinder 102 through the sharp points of the V-shaped plates, so that water flow carries bubbles between the upper baffle plates 302 and the lower baffle plates 302 to generate opposite flushing, the bubbles are broken, the contact area between gas and water is increased, second fan blades 303 in the annular array are fixedly connected in the three first rotating cylinders 301 in the linear array, the gas in the breather pipe 113 drives the second fan blades 303 to rotate, the second fan blades 303 rotate to drive the baffle plates 302 to stir the bubbles in the water washing cylinder 102 to break, the contact area between the gas and the water is increased, the baffle plates 302 are fixedly connected with mirror image distributed drainage blocks 304, and the drainage blocks 304 are located on the outer side surfaces of the baffle plates 302.

As shown in fig. 7, the ventilation pipe 113 is slidably connected with vibration rods 401 in annular distribution and in a linear array, a third reset spring 402 is arranged between each vibration rod 401 in annular distribution and in a linear array and the air outlet pipe 105, the third reset spring 402 is used for resetting the vibration rods 401, so that the vibration rods 401 impact the first rotary cylinder 301 to generate vibration force, the first rotary cylinder 301 is fixedly connected with first ejector blocks 403 in annular array, the first ejector blocks 403 are provided with arc surfaces in mirror image distribution, the first ejector blocks 403 in annular array are matched with the vibration rods 401, the first rotary cylinder 301 rotates to drive the first ejector blocks 403 to squeeze the vibration rods 401, the vibration rods 401 slide upwards along the ventilation pipe 113, when the first ejector blocks 403 are separated from the vibration rods 401, the vibration rods 401 are reset to impact the first rotary cylinder 301, impurities carried in air are prevented from adhering to the surface of the baffle plate 302, the flow guiding effect of the baffle plate 302 is reduced, and meanwhile the vibration force of the baffle plate 302 further enhances the effect of stirring and cracking of the baffle plate 302.

When the pressure accumulating plate 204 slides downwards along the drum 201 to the opening of the five air outlet sleeves 203, at this time, air flows in the ventilation pipe 113, the air can contact with and push the second blades 303 of the annular arrays in the first rotating drum 301 to rotate, the second blades 303 rotate to drive the adjacent first rotating drum 301 to synchronously rotate, the first rotating drum 301 rotates to drive the four baffle plates 302 of the annular arrays to synchronously rotate, the baffle plates 302 rotate to stir bubbles formed by the water washing air in the water washing drum 102, the bubbles in the stirring water of the baffle plates 302 break, the contact area of the air and the water is increased, meanwhile, the baffle plates 302 rotate to guide the water flow to the upper side and the lower side, the bubbles in the water flow to the upper side and the lower side, the water flow is opposite to the water flow, the inner bubbles are broken again by the opposite water flow, the contact area of the air and the water is further increased, the water flow is stirred by the baffle plates 302 to stir the water flow, the bubbles in the water flow are opposite to the water flow, the contact area of the air and the water is broken again, and the water washing efficiency is ensured.

In the rotation process of the first rotating cylinder 301, the first rotating cylinder 301 rotates to drive the first top blocks 403 of the annular arrays on the first rotating cylinder 301 to synchronously rotate, the first top blocks 403 of the annular arrays rotate to contact and press the vibration plates 401, the vibration plates 401 slide upwards along the ventilation pipes 113, meanwhile, the third reset springs 402 are compressed, when the first rotating cylinder 301 continues to rotate until the first top blocks 403 are separated from the vibration plates 401, the third reset springs 402 reset to drive the vibration plates 401 to synchronously reset, the vibration plates 401 reset to impact the first rotating cylinder 301, the first rotating cylinder 301 is impacted by the vibration plates 401 to generate vibration, the vibration force of the first rotating cylinder 301 is transmitted to four baffle plates 302 of the adjacent annular arrays, impurities carried in gas are prevented from being attached to the surfaces of the baffle plates 302, the flow guiding effect of the baffle plates 302 is reduced, and meanwhile, the vibration force of the baffle plates 302 further enhances the effect of stirring bubbles and cracking.

Example 3: on the basis of embodiment 2, as shown in fig. 5, fig. 6, fig. 8 and fig. 9, three baffle plates 302 located in the same vertical direction are fixedly connected with a cleaning rod 501, the cleaning rod 501 is attached to the inner wall of the main cylinder of the washing cylinder 102, the cleaning rod 501 is used for cleaning the inner wall of the washing cylinder 102, three cleaning frames 601 in annular arrays are rotatably connected with the washing cylinder 102, the three cleaning frames 601 in annular arrays are respectively located in three auxiliary cylinders of the washing cylinder 102, torsion springs 602 are arranged between the three cleaning frames 601 in annular arrays and the washing cylinder 102, the cleaning frames 601 are fixedly connected with a fixed outer plate 603, the fixed outer plate 603 is located at the communicating position of the main cylinder and the auxiliary cylinder of the washing cylinder 102, the fixed outer plate 603 is slidably connected with a push plate 604, a fourth reset spring 605 in linear array is arranged between the push plate 604 and the adjacent fixed outer plate 603, the push plate is matched with the cleaning rod 501, when the baffle plates 302 drive the cleaning rod 501 to rotate, the cleaning rod 501 is attached to the push plate 604, and the push plate 604 is synchronously rotated, the push plate 604 drives the driving frames 601 to rotate to clean the inner wall of the washing cylinder 102 around the cleaning ring 108, the impurities on the inner wall of the washing cylinder 102 are pushed by the push plate 601, and the impurities on the inner wall of the cleaning frame 102 are pushed by the push plate 601 to rotate fast and the cleaning ring 108, and the impurities on the cleaning ring and the cleaning ring is guaranteed.

In the process that the first rotating cylinder 301 drives the four baffle plates 302 of the annular array to rotate, the three baffle plates 302 in the same vertical direction drive the cleaning rod 501 to synchronously rotate, the cleaning rod 501 rotates to clean impurities attached to the inner wall of the washing cylinder 102, meanwhile, when the cleaning rod 501 rotates to be in contact with the push plate 604, the cleaning rod 501 pushes the push plate 604, the push plate 604 is pushed by the cleaning rod 501 to drive the cleaning frame 601 to rotate, the torsion spring 602 is twisted, the cleaning frame 601 rotates to clean impurities on the inner wall of the washing cylinder 102 around the float 108, the impurities on the periphery of the float 108 are prevented from obstructing the sliding, the height of the water level in the washing cylinder 102 cannot be accurately detected, when the push plate 604 contacts with the inner wall of the washing cylinder 102, the cleaning rod 501 extrudes the push plate 604 to inwards slide along the fixed outer plate 603, meanwhile, the fourth reset spring 605 of the linear array is compressed until the cleaning rod 501 is separated from the push plate 604, at this moment, the torsion spring 602 resets to drive the cleaning frame 601 to synchronously reset, the fourth reset spring 605 resets the cleaning frame 604 synchronously reset until the cleaning frame 604 is pushed by the cleaning frame 501 again, the cleaning frame 601 is pushed by the cleaning frame 601, the impurities on the periphery of the inner wall of the washing cylinder 102 is prevented from being blocked by the impurities on the periphery of the cleaning frame 102, and the impurities on the periphery of the inner wall of the washing cylinder 102 can stably slide.

Example 4: on the basis of embodiment 3, as shown in fig. 5, 10 and 11, the water washing barrel 102 is fixedly connected with a second top block 701 of an annular array, the second top block 701 is provided with an arc surface distributed in a mirror image mode, the vent pipe 113 is rotationally connected with a second rotating barrel 702, a third fan blade 703 of the annular array is fixedly connected in the second rotating barrel 702, the third fan blade 703 is in contact with gas in the vent pipe 113 to rotate, simultaneously, the second rotating barrel 702 is driven to synchronously rotate, the outer wall of the second rotating barrel 702 is fixedly connected with a fixing frame 704, the fixing frame 704 is slidingly connected with a push rod 705, the lower end of the push rod 705 is fixedly connected with a material taking basket 706, the material taking basket 706 is used for collecting impurities floating on the liquid surface in the water washing barrel 102, a tension spring 707 is arranged between the fixing frame 704 and the material taking basket 706, the second top block 701 of the annular array is matched with the push rod 705, the push rod 705 is enabled to enable the push rod 705 to drive the material taking basket 706 to enter below the liquid surface, when the second top block 703 is separated from the push rod 705, the push rod 706 is driven to reset to enable the impurities in the push rod 705 to float in the water surface, the material taking basket 705 is difficult to float in the water washing barrel 102 due to the fact that the impurities float in the water washing barrel is difficult to float in the water washing barrel 102.

In the process that the gas circulates in the ventilation pipe 113, the gas passes through the second rotating cylinder 702 and contacts with the third fan blades 703 in the annular array in the second rotating cylinder, the gas contacts with the third fan blades 703 to push the third fan blades 703 to rotate, the third fan blades 703 rotate to drive the second rotating cylinder 702 to synchronously rotate, the second rotating cylinder 702 rotates to drive the fixing frame 704 to synchronously rotate, the fixing frame 704 rotates to drive the upper push rod 705 to synchronously rotate, the push rod 705 rotates to contact with the second jacking block 701 in the annular array above, the second jacking block 701 extrudes the push rod 705, the push rod 705 slides downwards along the fixing frame 704, meanwhile, the tension spring 707 is stretched, the push rod 705 slides along the fixing frame 704 to drive the material taking basket 706 to enter the position below the water level in the washing cylinder 102, when the push rod 705 is separated from the second jacking block 701, the tension spring 707 resets to drive the push rod 705 to reset, the material taking basket 706 moves upwards to float in the impurity pocket inside, excessive impurities floating in the water level in the washing cylinder 102 are avoided, the air is difficult to be discharged, and the circulation is completed until the washing of the air is finished.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (10)

1. The utility model provides a self-cleaning automatic liquid level control water washing device, its characterized in that, including base (101), base (101) fixedly connected with water wash bowl (102), water wash bowl (102) fixedly connected with and intercommunication have raceway (103), raceway (103) fixedly connected with intake pipe (104), water wash bowl (102) fixedly connected with and intercommunication have outlet duct (105), water wash bowl (102) fixedly connected with and intercommunication have outlet duct (106), fixed axle (107) of annular array are fixedly connected with in water wash bowl (102), annular array fixed axle (107) all sliding connection has cursory (108), cursory (108) fixedly connected with mirror image distributed first extrusion piece (109), cursory (108) with water wash bowl (102) sliding fit, mirror image distributed first extrusion piece (109) are located water wash bowl (102) outside, water wash bowl (102) sliding connection has mirror image distributed and annular array's second extrusion piece (110), first extrusion piece (109) and adjacent second extrusion piece (106) all sliding connection has seal plate (110) and straight line (112) that are connected with adjacent (103), the novel water inlet pipe is characterized in that a first reset spring (111) is arranged between the water outlet pipe (106) and the water delivery pipe (103) and the second extrusion block (110) which are adjacent to each other, a vent pipe (113) is fixedly connected in the base (101), and the vent pipe (113) is communicated with the air inlet pipe (104).

2. A self-cleaning automatic level control water washing device according to claim 1, characterized in that a gap is left between adjacent sealing plates (112) for circulating water.

3. The self-cleaning automatic liquid level control water washing device according to claim 1, wherein a rotary drum (201) is rotatably connected to the bottom of the ventilation pipe (113), a first fan blade (202) of an annular array is fixedly connected to the rotary drum (201), an air outlet sleeve (203) of the annular array is fixedly connected and communicated with the rotary drum (201), and the air outlet sleeve (203) of the annular array is located below the first fan blade (202).

4. A self-cleaning automatic liquid level control water washing device as claimed in claim 3, characterized in that a pressure accumulating plate (204) is slidably connected to the drum (201), and a second return spring (205) is arranged between the drum (201) and the pressure accumulating plate (204).

5. A self-cleaning automatic liquid level control water washing device as claimed in claim 3, wherein the breather pipe (113) is rotatably connected with a first rotary cylinder (301) of a linear array, the first rotary cylinders (301) of the linear array are all fixedly connected with baffle plates (302) of an annular array, second fan blades (303) of the annular array are all fixedly connected in the first rotary cylinders (301) of the linear array, and the baffle plates (302) are fixedly connected with drainage blocks (304) distributed in a mirror image mode.

6. The self-cleaning automatic liquid level control water washing device according to claim 5, wherein the baffle plate (302) is a transversely placed V-shaped plate, the sharp point of the baffle plate (302) faces in the same direction as the rotation direction of the first rotating cylinder (301), and the drainage block (304) is located on the outer side surface of the baffle plate (302).

7. The self-cleaning automatic liquid level control water washing device according to claim 5, wherein the ventilation pipe (113) is slidably connected with vibration rods (401) which are distributed in an annular mode and are in linear arrays, a third reset spring (402) is arranged between the vibration rods (401) and the ventilation pipe (113), a first top block (403) which is in an annular array is fixedly connected in the first rotary cylinder (301), and the first top block (403) which is in an annular array is matched with the vibration rods (401).

8. The self-cleaning automatic liquid level control water washing device according to claim 6, wherein the baffle plates (302) located in the same vertical direction are fixedly connected with a cleaning rod (501) together, and the cleaning rod (501) is used for cleaning the inner wall of the water washing cylinder (102).

9. The self-cleaning automatic liquid level control water washing device according to claim 8, wherein a cleaning frame (601) of an annular array is rotationally connected to the water washing cylinder (102), torsion springs (602) are arranged between the cleaning frame (601) of the annular array and the water washing cylinder (102), a fixed outer plate (603) is fixedly connected to the cleaning frame (601), a push plate (604) is slidably connected to the fixed outer plate (603), a fourth return spring (605) of a linear array is arranged between the push plate (604) and the adjacent fixed outer plate (603), and the push plate (604) is matched with the cleaning rod (501).

10. The self-cleaning automatic liquid level control water washing device according to claim 9, wherein the water washing barrel (102) is fixedly connected with a second top block (701) of an annular array, the ventilation pipe (113) is rotatably connected with a second rotating barrel (702), a third fan blade (703) of the annular array is fixedly connected in the second rotating barrel (702), the second rotating barrel (702) is fixedly connected with a fixing frame (704), the fixing frame (704) is slidably connected with a push rod (705), the push rod (705) is fixedly connected with a material taking basket (706), a tension spring (707) is arranged between the fixing frame (704) and the material taking basket (706), and the second top blocks (701) of the annular array are matched with the push rod (705).