CN113856898A - Iron removing method and iron removing device using same - Google Patents

Abstract

The invention provides an iron removal method and an iron removal device using the same, wherein the iron removal method comprises the following steps: s1, under the drive of the drive assembly, the iron absorption assembly is input from the input end of the iron removal area, and the slurry in the iron removal area is subjected to iron removal treatment and is output from the output end of the iron removal area; s2, cleaning the output iron absorption assembly, and guiding the cleaned iron absorption assembly to return to the input end, so as to finish a deironing period of the iron absorption assembly; s3, repeating the steps S1 and S2 to enable the magnet assembly to execute the application with a plurality of iron removal cycles; in step S2, the output end is higher than the input end, and outside the deironing region, a guiding component is disposed between the output end and the input end; under the action of gravity, the output magnet assembly is guided to move to the input end along the guide track of the guide assembly, and the magnet assembly in the guiding movement is cleaned. The iron removing method can realize the circulating iron removing cleaning and reduce the influence caused by mechanical fatigue.

Description

Iron removing method and iron removing device using same

Technical Field

The invention relates to the technical field of iron removal, in particular to an iron removal method and an iron removal device using the same.

Background

In the application of the prior art, adsorption is generally carried out by adopting equal and fixed adsorption parts, so that the iron is inconvenient to remove and then the iron is cleaned; in addition, circular iron removal and automatic cleaning cannot be realized mostly, and the adsorption part needs to be manually operated to switch between an iron removal state and a cleaning state; during cleaning, slurry feeding is required to be stopped, the working efficiency is low, and slurry adhered to the iron removal area can be cleaned at the same time, so that a large amount of slurry is wasted; the iron removal time and the cleaning time of the adsorption component are not adjusted, so that the utilization efficiency of the adsorption component is low; after long-time use, the mechanical fatigue generated by the device can cause unsmooth operation; the device is bulky, resulting in a larger footprint.

Disclosure of Invention

The invention aims to provide an iron removing method and an iron removing device using the same to overcome the defects of the prior art.

The iron removal method comprises the following steps:

s1, under the drive of the drive assembly, the iron absorption assembly is input from the input end of the iron removal area, and the slurry in the iron removal area is subjected to iron removal treatment and is output from the output end of the iron removal area;

s2, cleaning the output iron absorption assembly, and guiding the cleaned iron absorption assembly back to the input end, so as to finish a deironing period of the iron absorption assembly;

s3, repeating the steps S1 and S2 to enable the iron absorption assembly to execute the application with a plurality of iron removal cycles;

in step S2, the horizontal height of the output end is higher than the horizontal height of the input end, and a guiding component is disposed between the output end and the input end outside the deironing region; under the action of gravity, the output magnet assembly is guided to move to the input end along the guide track of the guide assembly, and the magnet assembly in the guiding movement is cleaned.

Specifically, in step S1, when the magnet assembly is set to be in a disk shape, the magnet assembly moves in a "V" shape in the iron removing area during the iron removing process.

Specifically, the iron attracting assembly is arranged in the iron removing area along the movement track, and the movement bending angle of the iron attracting assembly is 90 degrees.

Specifically, a plurality of groups of the magnet assemblies are arranged, and each group of the magnet assemblies are closely arranged in the iron removing area; under the drive of the drive assembly, when one group of the magnet assemblies at the input end move towards the iron removal area, the other group of the magnet assemblies at the output end in linkage are output to the outside of the iron removal area.

Specifically, in step S1, when the magnet assemblies are spherical or cylindrical, the iron removal region is in a downward-concave arc shape, each set of the magnet assemblies is closely arranged along the shape of the iron removal region, and under the guidance of the iron removal region, the driving assembly drives one set of the magnet assemblies to be input from the input end to the iron removal region, and is linked with another set of the magnet assemblies located in the iron removal region to be output from the output end to the outside of the iron removal region.

Specifically, in step S2, a transportation component is applied, the transportation component performs transportation motion along the guiding track of the guiding component, and the output magnet component performs guiding motion to the input end along the guiding track of the guiding component under the action of gravity and the driving of the transportation component; the transportation component is used for limiting the magnet assembly, so that the magnet assembly in cleaning is prevented from deviating and falling off from the guide assembly.

Specifically, the guide track of the guide assembly is in a shape of a slanted straight line or an arc.

Specifically, the slurry enters the iron removal area from the output end, and flows out of the iron removal area from the input end after iron removal treatment.

Specifically, in the iron removing period, the time that the iron absorbing assembly is located in the iron removing area is longer than the time that the iron absorbing assembly is located outside the iron removing area.

The iron removal device is applied to the iron removal method and comprises the iron removal area, the input end, the output end and the guide assembly, wherein one end of the guide assembly corresponds to the input end, and the other end of the guide assembly corresponds to the output end.

The invention has the beneficial effects that:

1. the iron removing method enables the iron absorption assembly to form an iron removing period, and realizes the cyclic iron absorption application and the cleaning application; under the action of gravity, the output iron absorption assembly is guided to move to the input end along the guide track of the guide assembly, so that the operation process of the iron absorption assembly is smoother, and the problem of unsmooth operation caused by mechanical fatigue generated after the iron removing device is used for a long time is solved; the driving assembly is arranged in a matched manner to drive the iron attracting assembly to sequentially pass through the input end, the iron removing area and the output end, so that the automatic circulation of the iron removing period is realized; through the deironing washing application that forms continuous cycle, need not to stop thick liquid and wash, greatly improved work efficiency, and make the magnet subassembly wash outside the deironing region, can not wash the thick liquids of the regional interior adhesion of deironing, it is extravagant to have reduced a large amount of unnecessary thick liquids, reaches the effect of saving thick liquids.

2. The arrangement that the magnet assembly moves in a V-shaped track in the iron removing area is convenient for the disc-shaped magnet assembly to input along the axial direction and output along the radial direction.

3. Through setting up the iron subassembly of inhaling that the multiunit was closely arranged according to input, deironing region, output in proper order, form the linkage between the iron subassembly of inhaling, reduced the distance that the iron subassembly was inhaled in the drive assembly drive, consequently can use the drive assembly of less effect distance to reduce drive assembly's volume, reached the effect of saving space.

4. The spherical or cylindrical iron absorbing assembly can be linked under the driving of the driving assembly through the arrangement that the iron removing area is in a concave arc shape.

5. Through the arrangement of the conveying component, the iron absorbing assembly after being output returns to the input end along the guide track of the guide assembly.

6. The guide track is set to be in an inclined linear shape or a concave arc shape, so that the iron attracting assembly can utilize gravity to a greater extent, and the fluency of the iron attracting assembly in the transportation process is enhanced.

7. Through the opposite arrangement of the flow direction of the slurry in the iron removing area and the movement direction of the iron absorbing assembly in the iron removing area, the opposite impact of the slurry and the iron absorbing assembly is realized, and the iron removing effect is enhanced.

8. The iron removing method ensures that the time of the iron absorption assembly in the iron removing area is longer than the time of the iron absorption assembly outside the iron removing area, thereby improving the utilization efficiency of the iron absorption assembly.

Drawings

FIG. 1 is a schematic view showing an output state of the magnet assembly in the first embodiment;

FIG. 2 is a schematic view showing a state where the magnet assembly is cleaned in the first embodiment;

FIG. 3 is a schematic view taken from perspective A perpendicular to the guide plane of FIG. 2;

FIG. 4 is a schematic view showing an input state of the magnet assembly in the first embodiment;

FIG. 5 is a schematic view showing a cleaning state of the magnet assembly in the second embodiment.

Description of reference numerals:

the device comprises an input half area 1, an input end 11, a first magnetizing body 12, an output half area 2, an output end 21, a second magnetizing body 22, an iron attracting assembly 3, a driving assembly 4, an input assembly 41, a first push rod 411, a first push portion 4111, a first power cylinder 412, an output assembly 42, a second push rod 421, a second push portion 4211, a second power cylinder 422, a rotating rod 51, a sliding groove 511, a rotating shaft 512, a push-pull groove 513, a transportation frame 52, an accommodating cavity 520, a sliding seat 521, a guide rail 522, a push-pull assembly 53, a push-pull rod 531, a push-pull seat 5311, a push-pull cylinder 532, a cleaning area 6, a cleaner 61, a scrap iron groove 62, a slurry return opening 7 and a valve 71.

Detailed Description

In order to make the technical solution, the purpose and the advantages of the present invention more apparent, the present invention will be further explained with reference to the accompanying drawings and embodiments.

The first embodiment shown in fig. 1 to 4 includes:

the deironing is regional, and the deironing is regional to be equipped with direction input 11, direction output 21 up, and the level of output 21 is higher than the level of input 11, is provided with washing region 6 outside the deironing region, still includes to be equipped with the direction subassembly between input 11 and output 21, and the direction orbit of direction subassembly is through washing region 6 settings. Under the drive of the driving component 4, the iron absorption component 3 is input from the input end 11, the slurry in the iron removal area is subjected to iron removal treatment and is output from the output end 21, and the output iron absorption component 3 is guided to move to the input end 11 along the guide track of the guide component under the action of gravity, so that the transportation process of the iron absorption component 3 is smoother, and the unsmooth transportation caused by mechanical fatigue after long-time use is overcome; cleaning the magnet assembly 3 in the guiding movement; so as to effectively execute the next round of iron removal application; thereby form continuous cycle's deironing and wash the application, need not to stop thick liquid and wash, greatly improved work efficiency, and make the magnet subassembly wash outside the deironing region, can not wash the thick liquids of the regional interior adhesion of deironing, reduced a large amount of unnecessary thick liquids extravagant, reach the effect of saving thick liquids.

Based on practical application, the iron attracting assemblies 3 are provided with a plurality of groups, each group of iron attracting assemblies 3 are arranged in the iron removing area in a closely distributed mode, and when one group of iron attracting assemblies 3 at the input end 11 moves into the iron removing area, the other group of iron attracting assemblies 3 at the output end 21 in linkage mode are output to the outside of the iron removing area; because the horizontal height of the output end 21 is higher than that of the input end 11, the slurry enters the iron removing area from the output end 11, after the iron removing treatment, the slurry flows out of the iron removing area from the input end 21 under the action of hydraulic pressure, and because the flow direction of the slurry in the iron removing area is opposite to the movement direction of the iron absorbing component 3 in the iron removing area, the iron absorbing component 3 and the slurry realize the opposite impact, and the iron removing effect is enhanced; when the iron absorption component 3 is in the iron removing period, the time that the iron absorption component 3 is in the iron removing area is longer than the time that the iron absorption component is out of the iron removing area, so that the utilization efficiency of the iron absorption component is improved.

The guide assembly comprises two guide rails 522 which are in an inclined straight rod shape, the two guide rails 522 are arranged in parallel to enable a guide plane to be formed on the upper side of the guide rails 522, the guide tracks of the guide planes are arranged in an inclined straight line shape, and the distance between the two guide rails 522 is smaller than the width of the magnet assembly 3, so that the magnet assembly 3 does guide movement along the guide rails 522 and does not fall off; the transportation component carries out reciprocating transportation motion along the guide track of the guide plane, and the output iron attracting component 3 carries out guide motion to the input end 11 along the guide track of the guide component under the action of gravity and the driving of the transportation component; the transportation part limits the magnet assembly 3, so that the magnet assembly 3 is prevented from deviating and falling off from the guide assembly during cleaning; in the cleaning area 6, a cleaner 61 is arranged above the guide rail 522 to clean the sucker assembly 3; a scrap iron receptacle 62 is provided below the guide rail 522 to collect iron falling from the magnet assembly 3.

The deironing assembly 3 is in a disc shape, the deironing area comprises an input half area 1 and an output half area 2, an input end 11 is arranged at one end of the input half area 1, an output end 21 is arranged at one end of the output half area 2, the other end of the input half area 1 is communicated with the other end of the output half area 2 to form a communicating area, and the input half area 1 and the output half area 2 are arranged in a V shape; the driving assembly 4 comprises an input assembly 41 arranged at the input end 11 and used for guiding the magnet assembly 3 to be input towards the input half-area 1, and an output assembly 42 arranged at the communication position and used for guiding the magnet assembly 3 to be output towards the output end 21; the angle of intersection between the input half-area 1 and the output half-area 2 is 90 degrees, so that the disc-shaped magnet assembly 3 can be conveniently input along the axial direction and output along the radial direction.

In actual use, the input assembly 41, the output assembly 42 and the transportation component sequentially and circularly work, and the working principle of the first embodiment is as follows:

one group of the magnet assemblies 3 are input to the input half area 1 along the axial direction through the input end 11 under the action of the input assembly 41, and are linked with the other group of the magnet assemblies 3 positioned in the input half area 1 to move to the communication area, the moving direction of the magnet assemblies 3 moving from the input half area 1 to the communication area is deflected by ninety degrees along the axial direction to the radial direction, then the magnet assemblies are moved to the output half area 2 under the action of the output assembly 42, and are linked with the other group of the magnet assemblies 3 positioned in the output half area 2 to be output to the transportation part along the radial direction through the output end 21, then the transportation part enters the cleaning area 6 to be cleaned along with the transportation movement of the transportation part, the iron assemblies 3 continuously move to the input end 11 after the cleaning is finished, and finally the transportation part is reset to the output end 21, the magnet assemblies 3 falling into the input end 11 are driven by the input assembly 41 to carry out the iron removal work of the next round, so far, the iron removing period is completed once, and the iron removing period is repeated, so that the iron absorption component 3 executes the application with the iron removing period for a plurality of times to remove iron.

Based on the first embodiment described above, the second embodiment shown in fig. 5 differs as follows:

the iron absorption component 3 is arranged in a spherical or cylindrical shape, the iron removing area is in a concave arc shape, and the rest of the application is the same; during practical use, the driving assembly 4 and the transportation part sequentially and circularly work, and the working principle of the second embodiment is as follows:

a set of magnet subassembly 3 is inputed to the deironing region by input 11 under drive assembly 4's effect, under curved structural action, the linkage is located magnet subassembly 3 in the deironing region and is exported to transport part by output 21, it washs to enter into washing region 6 along with transport part's transportation motion again, continue to move to input 11 department after the washing is accomplished, thereby fall into input 11, transport part resets to output 21 department at last, the magnet subassembly 3 that falls into input 11 then carries out the deironing work of next round by drive assembly 4 drive, up to this time accomplish the deironing cycle, repeat above deironing cycle, make magnet subassembly 3 carry out the application that has many times deironing cycle, in order to carry out the deironing.

In combination with the first embodiment, the second embodiment, and the third embodiment, the differences are as follows; the guide assembly comprises two guide rails 522 in the shape of a concave arc rod, the two guide rails 522 are arranged in parallel to each other so that a guide plane is formed on the upper side of the guide rails 522, and the guide tracks of the guide plane are arranged in the shape of a concave arc; the rest of the applications are the same, and are not described in detail here.

In combination with the above-described embodiments of the iron removal device, preferred embodiments of the components are as follows:

the iron attracting assembly 3 selects a magnetic medium in the prior art, a magnetic field is arranged in the iron removing area, and the iron attracting assembly 3 is magnetized in the magnetic field to generate magnetism, so that iron in the slurry is adsorbed; the iron absorption assembly 3 loses magnetism after leaving the magnetic field, and the absorbed iron falls into the scrap iron groove 62 from the iron absorption assembly 3, so that the iron absorption assembly 3 is convenient to clean; accordingly, in the first embodiment, the first magnetizing body 12 is disposed around the outside of the input half-area 1, the second magnetizing body 22 is disposed around the outside of the output half-area 2, and the first magnetizing body 12 and the second magnetizing body 22 can be implemented by using an inductance coil or a permanent magnet in the prior art, so as to generate a magnetic field.

The transportation part comprises a transportation frame 52, a rotating rod 51 and a push-pull assembly 53, wherein the transportation frame 52 is provided with a containing cavity 520 for loading the magnet assembly 3, the containing cavity 520 is vertically arranged in a run-through manner, so that a cleaning opening for cleaning the magnet assembly 3 is formed at the upper side of the transportation frame 52, and a placing opening for placing the magnet assembly 3 is formed at the lower side of the transportation frame; the rotating rod 51 is connected with a rotating shaft 512 to form a rotating connection, one side of the rotating rod 51, which is opposite to the rotating shaft 512, is provided with a sliding groove 511 arranged in a long-strip hole shape, the other side of the rotating rod 51 is provided with a push-pull groove 513 arranged in a long-strip hole shape, the transportation frame 52 is connected in the sliding groove 511 in a sliding manner through a sliding seat 521, and the movable end of the push-pull assembly 53 is connected in the push-pull groove 511 in a sliding manner through a push-pull seat 5311; when the push-pull assembly 53 is pushed or pulled, the push-pull slot 513 is slidably engaged with the sliding slot 511 to push the rotating rod 51 to rotate around the rotating shaft 512, so as to drive the transporting frame 52 to reciprocate along the guiding track of the guiding plane.

Based on the specific arrangement of the transportation component, the distance between the center position of the sliding groove 511 and the center position of the rotation shaft 512 is greater than the distance between the center position of the rotation shaft 512 and the center position of the push-pull groove 513, thereby forming a structure similar to a lever, when the push component 53 pushes the rotation rod 51 to rotate around the rotation shaft 512, due to the lever action, the movement distance of the rotation rod 51 driving the transportation frame 52 is greater than the movement distance of the push component 53 pushing the rotation rod 51, therefore, the iron removing device can use the push component 53 with smaller action distance, thereby reducing the volume of the push component 53, saving the space in the machine body, and achieving the effect of reducing the volume of the iron removing device. In the first embodiment, the width of the input end 11 is slightly larger than the width of the magnet assembly 3, the width of the output end 21 is slightly larger than the thickness of the magnet assembly 3 and smaller than the width of the magnet assembly 3, and the height of the accommodating cavity 520 is not smaller than the width of the magnet assembly 3, so that the magnet assembly 3 cannot be output to the outside of the accommodating cavity 520, cannot fall back into the output half-area 2, and can be dumped in the accommodating cavity 520 under the action of gravity; in the second embodiment, the width of the input end 11 and the width of the output end 21 are slightly larger than the width of the magnet assembly 3, and the height of the accommodating cavity 520 is larger than the width of the magnet assembly 3, so the magnet assembly 3 cannot be output to the outside of the accommodating cavity 520, and the magnet assembly 3 cannot fall back into the output half-area 2 due to the close arrangement of the magnet assembly 3.

The push-pull assembly 53 comprises a push-pull rod 531 and a push-pull cylinder 532, the front end of the push-pull rod 531 is the movable end of the push-pull assembly 53, the rear end of the push-pull rod 531 is connected in the push-pull cylinder 532 in a penetrating manner, and the push-pull rod 531 is driven by the push-pull cylinder 532 to push the rotating rod 51 to rotate back and forth; the input assembly 41 comprises a first push rod 411 and a first power cylinder 412, the first push rod 411 is connected in the first power cylinder 412 in a penetrating manner, and the first push rod 411 performs forward pushing movement of the first power cylinder 412 under the driving action of the first power cylinder 412; the output assembly 42 comprises a second push rod 421 and a second power cylinder 422, the second push rod 421 is connected in the second power cylinder 422 in a penetrating manner, and the second push rod 421 performs forward pushing movement of the second power cylinder 422 under the driving action of the second power cylinder 422; a first pushing part 4111 is arranged at the front end of the first pushing rod 411, and a second pushing part 4211 is arranged at the front end of the second pushing rod 421; the first power cylinder 412, the second power cylinder 422 and the push-pull cylinder 532 may be hydraulic cylinders, pneumatic cylinders or electric cylinders, which are well known in the art. The two rotating rods 51 are provided, the upper parts of the two rotating rods 51 are respectively slidably assembled with the sliding seats 521 at both sides of the transporting frame 52 through the sliding grooves 511, and the lower parts of the two rotating rods 51 are respectively slidably assembled with the push-pull seats 5311 at both sides of the front end of the push-pull rod 531 through the push-pull grooves 513.

But the regional low level department of deironing still is equipped with the returning thick liquid mouth 7 of switch, and returning thick liquid mouth 7 is equipped with valve 71, and returning thick liquid mouth 7 realizes the switch through valve 71, and the remaining thick liquids of this deironing device stop work of being convenient for can flow out the deironing region, and be convenient for can flow away the dirty water after the deironing region washs.

The above description is only a preferred embodiment of the present invention, and those skilled in the art may still modify the described embodiment without departing from the implementation principle of the present invention, and the corresponding modifications should also be regarded as the protection scope of the present invention.

Claims (10)

1. The iron removal method is characterized by comprising the following steps:

s1, under the drive of the drive assembly, the iron absorption assembly is input from the input end of the iron removal area, and the slurry in the iron removal area is subjected to iron removal treatment and is output from the output end of the iron removal area;

s2, cleaning the output iron absorption assembly, and guiding the cleaned iron absorption assembly back to the input end, so as to finish a deironing period of the iron absorption assembly;

s3, repeating the steps S1 and S2 to enable the iron absorption assembly to execute the application with a plurality of iron removal cycles;

in step S2, the level of the output terminal is higher than the level of the input terminal; a guide assembly is arranged between the output end and the input end outside the iron removing area, and the output iron absorbing assembly moves to the input end along the guide track of the guide assembly under the action of gravity; and cleaning the magnet assembly in the guiding movement.

2. The method for removing iron of claim 1, wherein in step S1, the magnet assembly moves in a "V" shaped track in the iron removal area during the iron removal process.

3. The method for removing iron in claim 2, wherein the magnet assembly has a trajectory with a bending angle of 90 degrees in the iron removal region.

4. The method for removing iron according to claim 1, wherein a plurality of sets of said magnet assemblies are provided, each set of said magnet assemblies being arranged in close proximity within said iron removal zone; under the drive of the drive assembly, when one group of the magnet assemblies at the input end move towards the iron removal area, the other group of the magnet assemblies at the output end in linkage are output to the outside of the iron removal area.

5. The method for removing iron in accordance with claim 4, wherein in step S1, the iron removing area is in a downward concave arc shape, each set of said iron absorbing assemblies is closely arranged along the shape of the iron removing area, and under the guidance of the iron removing area, the driving assembly drives one set of said iron absorbing assemblies to be input from the input end to the iron removing area and to be linked with another set of iron absorbing assemblies located in the iron removing area to be output from the output end to the outside of the iron removing area.

6. The method for removing iron according to claim 1, wherein in step S2, a transportation component is used, the transportation component performs transportation motion along the guiding track of the guiding component, and the output magnet component performs guiding motion along the guiding track of the guiding component to the input end under the action of gravity and the transportation component.

7. The iron removal method of any one of claims 1 to 6, wherein the guide track of the guide assembly is inclined in a straight or arc shape.

8. The method for removing iron according to any one of claims 1 to 6, wherein the slurry enters the iron removal area from the output end, and flows out of the iron removal area from the input end after being subjected to iron removal treatment.

9. The method for removing iron according to any one of claims 1 to 6, wherein said modules are placed in said iron removal cycle for a time greater than a time outside said iron removal zone.

10. The iron removal device is characterized in that the iron removal device is applied to the iron removal method according to any one of claims 1 to 9, and comprises the iron removal area, the input end, the output end and the guide assembly, wherein one end of the guide assembly is arranged corresponding to the input end, and the other end of the guide assembly is arranged corresponding to the output end.

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