CN111455449A

CN111455449A - Electrolytic current density control device

Info

Publication number: CN111455449A
Application number: CN202010412275.1A
Authority: CN
Inventors: 申明娥
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-05-15
Filing date: 2020-05-15
Publication date: 2020-07-28

Abstract

The invention relates to the field of chemical industry, in particular to an electrolytic current density control device. The invention aims to provide an electrolytic current density control device. An electrolytic current density control device comprises an outer framework, a control display, a first cleaning pool, a polishing pool, a second cleaning pool, a portal frame, a first slide rail, a first electric push rod, an anode contact rod, a fixing frame, a current density control mechanism, an anode mud auxiliary separation mechanism and an anode mud collection mechanism; the left part of the top end in the outer framework is welded with the first cleaning pool; the middle part of the top end in the outer framework is welded with the polishing pool. The invention achieves the effects of adjusting the density of the electrolytic contact pins on two sides of the curved surface of the metal object to accelerate the electrolytic polishing speed of the concave structure, avoiding overlarge polishing loss of the original convex part to deform the metal object, grinding the anode mud generated on the surface of the metal, reducing the labor hour consumption and recovering the metal components scattered in the anode mud.

Description

Electrolytic current density control device

Technical Field

The invention relates to the field of chemical industry, in particular to an electrolytic current density control device.

Background

A technology for selectively removing rough surface and improving surface finish degree by electrolyzing metal workpiece as anode in proper electrolyte includes such steps as electropolishing to increase the corrosion resistance of stainless steel, decrease the resistance of electric contact, preparing metallographic abrasive disk, improving the light reflecting performance of lighting lamp, increasing the precision of measuring tools, beautifying the daily necessities and handicraft, and polishing iron, steel, aluminium, copper, nickel and alloy.

To sum up, at present, there is a need to develop an electrolytic current density control device which adjusts the density of electrolytic contact pins at two sides according to the surface curved surface shape of a metal object to accelerate the electrolytic polishing speed of a concave structure, simultaneously prevents the excessive electrolysis of a convex structure, enables the polishing loss of the original convex part to be too large, enables the metal object to deform, polishes anode mud generated on the metal surface, enables the anode mud which does not fall off in time to fall off in time, reduces the working hour consumption, recovers the metal components scattered in the anode mud, and enhances the purpose of recycling resources, so as to overcome the defects that the distribution of the electrolytically polished curved surfaces is different, the electrolytic polishing speed of the curved surfaces is different, the speed of the convex surfaces is greater than that of the concave surfaces, the complete electrolytic polishing causes the excessive loss of the convex surfaces, the anode mud can not be separated in time, the electrolytic speed is affected, and the anode mud deposited at the bottom of an, the noble metal can not be recovered in time, and the anode mud is stored for a long time to cause acidification pollution.

Disclosure of Invention

The invention aims to overcome the defects that the distribution of electrolytically polished curved surfaces is different, the electrolytic polishing speed of the curved surfaces is different, the speed of a convex surface is greater than that of a concave surface, the loss of the convex surface is overlarge due to complete electrolytic polishing, meanwhile, anode mud cannot be separated in time, the electrolytic speed is influenced, the anode mud deposited at the bottom of an electrolytic cell cannot be cleaned in time, precious metals cannot be recovered in time, and the anode mud is stored for a long time to cause acidification pollution.

The invention is achieved by the following specific technical means:

an electrolytic current density control device comprises an outer framework, a control display, a first cleaning pool, a polishing pool, a second cleaning pool, a portal frame, a first slide rail, a first electric push rod, an anode contact rod, a fixing frame, a current density control mechanism, an anode mud auxiliary separation mechanism and an anode mud collection mechanism; the top of the left end of the outer framework is connected with a control display through a bolt; the left part of the top end in the outer framework is welded with the first cleaning pool; the middle part of the top end in the outer framework is welded with the polishing pool, and the top of the left end of the polishing pool is connected with the first cleaning; the right part of the top end in the outer framework is welded with a second cleaning pool, and the top of the left end of the second cleaning pool is connected with a polishing pool; the left part and the right part of the top end of the outer framework are both connected with the portal frame through bolts; an anode mud auxiliary separation mechanism is arranged at the top in the outer framework, and the left end of the anode mud auxiliary separation mechanism is connected with the polishing pool; the bottom end of the outer framework is provided with an anode mud collecting mechanism, and the right part of the top end of the anode mud collecting mechanism is connected with an anode mud auxiliary separating mechanism; a current density control mechanism is arranged in the middle of the polishing pool, and the bottom end of the current density control mechanism is connected with the outer framework; the top of the inner left end and the top of the inner right end of the portal frame are welded with the first sliding rail; the bottom of the left end and the bottom of the right end in the portal frame are welded with the anode contact rod; the right part of the outer surface of the first sliding rail is in sliding connection with the first electric push rod; the right part of the outer surface of the anode contact rod is provided with a fixing frame.

Furthermore, the current density control mechanism comprises a second electric push rod, a first sliding plate, a second sliding rail, a first motor, a bidirectional bevel gear, a first straight gear, a second straight gear, a bolt bevel gear disc, a second bevel gear, a first transmission wheel, a first shifting wheel, a second shifting wheel, a third bevel gear, a transmission disc, a right-angle intermittent group, a mounting frame, an annular sliding rail, a cathode contact rod and a spring discharge differentiator; the right end of the second electric push rod is connected with the first sliding plate through a bolt; the bottom end of the first sliding plate is connected with the second sliding rail in a sliding manner; the middle part of the top end of the first sliding plate is connected with a first motor through a bolt; the middle part of the right end of the first motor is inserted with the bidirectional bevel gear; a first bevel gear is arranged at the top of the left end of the bidirectional bevel gear; a third bevel gear is arranged at the top of the right end of the bidirectional bevel gear; the middle part of the top end of the first bevel gear is inserted into the first straight gear; the left rear part of the first straight gear is meshed with the second straight gear; the middle part of the top end of the second straight gear is inserted into the bolt bevel gear disc; the front middle part of the top end of the bolt bevel gear disc is meshed with the second bevel gear; the middle part of the rear end of the second bevel gear is spliced with the first transmission wheel; the top of the first driving wheel is in transmission connection with the first thumb wheel through a belt; the left top of the first shifting wheel is in transmission connection with the second shifting wheel through a belt; the right top of the first shifting wheel is in transmission connection with the third shifting wheel through a belt; the middle part of the top end of the third bevel gear is inserted into the transmission disc; the top end of the transmission disc is in transmission connection with the right-angle intermittent group through a round pin; the left part of the top end of the right-angle intermittent group is in transmission connection with the mounting frame, the middle part of the bottom end of the mounting frame is connected with the first thumb wheel, the bottom of the left end in the mounting frame is connected with the second thumb wheel, and the bottom of the right end in the mounting frame is connected with the third thumb wheel; the bottom of the left end and the bottom of the right end of the mounting rack are both connected with the annular slide rail in a sliding manner; the left middle part of the top end in the mounting frame and the right middle part of the top end in the mounting frame are welded with the cathode contact rod; the outer surface of the cathode contact rod is sleeved with the spring discharge differentiator, the middle bottom of the outer surface of the spring discharge differentiator is connected with the first thumb wheel, the left bottom of the outer surface of the spring discharge differentiator is connected with the second thumb wheel, and the right bottom of the outer surface of the spring discharge differentiator is connected with the third thumb wheel; the left part of the bottom end of the second electric push rod is connected with the outer framework; the bottom end of the second slide rail is connected with the outer framework; the outer surface of the mounting frame is connected with the polishing pool.

Furthermore, the anode slime auxiliary separation mechanism comprises a second driving wheel, a third driving wheel, a fourth driving wheel, a fifth driving wheel, a cam, a sixth driving wheel, a first screw rod, a first rotating frame, a third sliding rail, a fixing plate, a sponge plate, a four-step telescopic rod and a first return spring; the middle part of the left end of the second driving wheel is spliced with the third driving wheel through a round rod; the middle part of the left end of the third driving wheel is spliced with the fourth driving wheel through a round rod; the top end of the third transmission wheel is in transmission connection with a sixth transmission wheel through a belt; the top end of the fourth transmission wheel is in transmission connection with the fifth transmission wheel through a belt; the middle part of the left end of the fifth driving wheel is spliced with the cam through a round rod; the middle part of the left end of the sixth driving wheel is inserted with the first screw rod; the middle part of the outer surface of the first screw rod is rotationally connected with the first rotating frame; the top of the left end and the bottom of the left end of the first rotating frame are both in sliding connection with a third sliding rail; the left end of the third sliding rail is welded with the fixing plate; the top of the left end of the fixed plate is connected with a sponge plate through a bolt; the top of the right end of the fixed plate is welded with a fourth-order telescopic rod; the right part of the bottom end of the fourth-order telescopic rod is welded with the first return spring; the bottom end of the second driving wheel is connected with the anode mud collecting mechanism through a belt; the middle part of the right end of the second driving wheel is connected with the outer framework; the middle part of the left end of the fourth driving wheel is connected with the polishing pool; the middle part of the left end of the polishing pool is connected with the polishing pool; the left end of the first screw rod is connected with the polishing pool; the left top of the outer surface of the first rotating frame and the left bottom of the outer surface of the first rotating frame are both connected with the polishing pool; the right end of the fourth-order telescopic rod is connected with the polishing pool; the bottom end of the first return spring is connected with the polishing pool.

Furthermore, the anode mud collecting mechanism comprises a second motor, a third electric push rod, a third straight gear, a fourth straight gear, a seventh transmission wheel, an eighth transmission wheel, a ninth transmission wheel, a tenth transmission wheel, an eleventh transmission wheel, a fifth straight gear, a sixth straight gear, a second screw rod, a second rotating frame, a first screen plate, a seventh straight gear, a first rectangular rotating frame, a third rotating frame, a second screen plate, an eighth straight gear and a second rectangular rotating frame; the bottom end of the second motor is welded with the third electric push rod; the middle part of the left end of the second motor is spliced with a third straight gear; a fourth straight gear is arranged at the rear part of the top end of the third straight gear; a sixth straight gear is arranged at the front part of the bottom end of the third straight gear; the middle part of the right end of the fourth straight gear is spliced with the seventh transmission wheel; the middle part of the right end of the seventh driving wheel is spliced with the eighth driving wheel; the top end of the eighth driving wheel is spliced with the ninth driving wheel through a belt; the left end of the ninth driving wheel is spliced with the tenth driving wheel through a round rod; the bottom of the tenth driving wheel is in transmission connection with an eleventh driving wheel through a belt; the middle part of the right end of the eleventh transmission wheel is spliced with the fifth straight gear; the middle part of the left end of the sixth straight gear is inserted with the second screw rod; the right middle part of the outer surface of the second screw rod is rotationally connected with the second rotating frame; the top end of the second rotating frame is rotationally connected with the first screen plate; the middle part of the right end of the first screen plate is spliced with a seventh straight gear; the right part of the outer surface of the first screen plate is in sliding connection with the first rectangular rotating frame; the left middle part of the outer surface of the second screw rod is rotationally connected with a third rotating frame; the top end of the third rotating frame is rotationally connected with the second screen plate; the middle part of the left end of the second net plate is inserted with the eighth straight gear; the left part of the outer surface of the eighth straight gear is in sliding connection with the second rectangular rotating frame; the bottom end of the third electric push rod is connected with the outer framework; the top end of the seventh transmission wheel is connected with the second transmission wheel through a belt; the middle part of the right end of the eighth driving wheel is connected with the outer framework; the middle part of the right end of the ninth driving wheel is connected with the outer framework; the middle part of the left end of the ninth driving wheel is connected with the polishing pool through a round rod; the right part of the outer surface of the first screen plate is connected with a polishing pool; the middle part of the left end of the first rectangular rotating frame is connected with the polishing pool; the left part of the outer surface of the second screen plate is connected with the polishing pool; the middle part of the right end of the second rectangular rotating frame is connected with the polishing pool.

Furthermore, the right-angle intermittent group comprises a first transmission rod, a limiting sleeve, a second transmission rod, a third transmission rod, a first triangular plate, a first pawl, a second return spring, a second triangular plate, a second pawl, a third return spring and a four-corner ratchet wheel; the left part of the outer surface of the first transmission rod is in sliding connection with the limiting sleeve; the left end of the first transmission rod is hinged with the second transmission rod; the left end of the first transmission rod is hinged with the third transmission rod; the left bottom of the rear end of the second transmission rod is in transmission connection with the first triangular plate; the left top of the rear end of the third transmission rod is in transmission connection with the second triangular plate, and the right bottom of the front end of the second triangular plate is connected with the first triangular plate; the left bottom of the rear end of the first triangular plate is rotationally connected with the first pawl; the middle part of the front end bottom of the first triangular plate is connected with a second return spring, and the bottom end of the second return spring is connected with a first pawl; the left top of the rear end of the second triangular plate is rotationally connected with the second pawl; the left middle part of the front end of the second triangular plate is connected with a third return spring, and the left end of the third return spring is connected with a second pawl; the right bottom of the rear end of the second triangular plate is rotationally connected with the four-corner ratchet wheel, the middle of the bottom end of the second triangular plate is connected with the first pawl, and the left of the top end of the second triangular plate is connected with the second pawl; the right part of the front end of the first transmission rod is connected with the transmission disc; the bottom end of the limiting sleeve is connected with the outer framework; the middle part of the top end of the four-corner ratchet wheel is connected with the mounting frame.

Furthermore, an electromagnetic block is arranged at the bottom end of the first electric push rod, and an electromagnetic block is arranged at the top end of the fixing frame.

Further, the spring discharge differentiator is provided as an interleaved combination of the tip contact pins and the springs.

Furthermore, the four corners of the four-corner ratchet wheel are respectively provided with a triangular bulge, and the combination is in a windmill shape.

Compared with the prior art, the invention has the following beneficial effects:

in order to solve the problems that the curved surfaces of the electrolytic polishing are distributed differently, the electrolytic polishing speed of the curved surfaces is different, the speed of the convex surfaces is higher than that of the concave surfaces, the convex surfaces are damaged too much due to the complete electrolytic polishing, meanwhile, anode mud cannot be separated timely, the electrolytic speed is influenced, the anode mud silts at the bottom of an electrolytic cell cannot be cleaned timely, precious metals cannot be recovered timely, and the anode mud is stored for a long time to cause acidification pollution, a current density control mechanism, an anode mud auxiliary separation mechanism and an anode mud collection mechanism are designed, the density of electrolytic contact pins at two sides is adjusted according to the curved surface shape of the surface of a metal object through the current density control mechanism, so that after the current is switched on, the concave part of the metal object is subjected to electrolytic treatment through a high-density side, then the convex part of the metal object is subjected to electrolytic treatment by using one side with lower density, meanwhile, the projecting structure is prevented from being excessively electrolyzed, so that the polishing loss of the original projecting part is large, the metal object is deformed, then the anode mud auxiliary separation mechanism is used for being close to the metal object to rub the metal surface, the anode mud generated on the metal surface is polished, the anode mud which does not fall off in time is caused to fall off in time, the speed of electrolytic polishing is kept, the labor hour consumption is reduced, then the anode mud falling into the bottom of the polishing pool is collected by the anode mud collection mechanism, after the processing is finished and the electrolytic polishing liquid is discharged, the anode mud is taken out and the anode mud collection mechanism is turned over to collect, so that the metal components scattered in the anode mud are recovered, the recycling of resources is enhanced, the electrolytic polishing speed of the density concave structure is accelerated according to the surface form of the metal object by adjusting the electrolytic contact pins at two sides, and the projecting structure is prevented from being excessively electrolyzed, the polishing loss of the original convex part is overlarge, so that the metal object is deformed, the anode mud generated on the surface of the metal is polished, the anode mud which does not fall off in time falls off in time, the man-hour consumption is reduced, the metal components scattered in the anode mud are recovered, and the purpose of recycling resources is enhanced.

Drawings

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

FIG. 2 is a schematic view of a fixing frame according to the present invention;

FIG. 3 is a schematic structural diagram of a current density control mechanism according to the present invention;

FIG. 4 is a schematic structural diagram of an auxiliary anode slime separating mechanism according to the present invention;

FIG. 5 is a schematic structural view of an anode slime collecting mechanism according to the present invention;

FIG. 6 is a schematic diagram showing the position distribution of a third electric push rod, a third spur gear, a fourth spur gear and a sixth spur gear according to the present invention;

FIG. 7 is a schematic view of a first mesh panel structure of the present invention;

FIG. 8 is a schematic view of a first rectangular rotating frame according to the present invention;

FIG. 9 is a schematic view of a right angle batch group configuration of the present invention;

FIG. 10 is an enlarged view of the structure of zone Z of the present invention.

The labels in the figures are: 1-an outer framework, 2-a control display, 3-a first cleaning pool, 4-a polishing pool, 5-a second cleaning pool, 6-a portal frame, 7-a first slide rail, 8-a first electric push rod, 9-an anode contact rod, 10-a fixed frame, 11-a current density control mechanism, 12-an anode mud auxiliary separation mechanism, 13-an anode mud collection mechanism, 1101-a second electric push rod, 1102-a first sliding plate, 1103-a second slide rail, 1104-a first motor, 1105-a bidirectional bevel gear, 1106-a first bevel gear, 1107-a first straight gear, 1108-a second straight gear, 1109-a bolt conical fluted disc, 11010-a second bevel gear, 11011-a first transmission wheel, 11012-a first thumb wheel and 11013-a second thumb wheel, 11014-a third thumb wheel, 11015-a third bevel gear, 11016-a transmission disc, 11017-a right-angle intermittent group, 11018-a mounting rack, 11019-an annular sliding rail, 11020-a cathode contact rod, 11021-a spring discharge differentiator, 1201-a second transmission wheel, 1202-a third transmission wheel, 1203-a fourth transmission wheel, 1204-a fifth transmission wheel, 1205-a cam, 1206-a sixth transmission wheel, 1207-a first screw rod, 1208-a first rotating rack, 1209-a third sliding rail, 12010-a fixed plate, 12011-a sponge plate, 12012-a fourth-order telescopic rod, 12013-a first reset spring, 1301-a second motor, 1302-a third electric push rod, 1303-a third spur gear, 1304-a fourth spur gear, 1305-a seventh transmission wheel, 1306-an eighth transmission wheel, 1307-a ninth transmission wheel, 1308-a tenth transmission wheel, 1309-an eleventh transmission wheel, 13010-a fifth spur gear, 13011-a sixth spur gear, 13012-a second screw rod, 13013-a second rotating frame, 13014-a first screen plate, 13015-a seventh spur gear, 13016-a first rectangular rotating frame, 13017-a third rotating frame, 13018-a second screen plate, 13019-an eighth spur gear, 13020-a second rectangular rotating frame, 1101701-a first transmission rod, 1101702-a limit sleeve, 1101703-a second transmission rod, 1101704-a third transmission rod, 1101705-a first triangular plate, 1101706-a first pawl, 1101707-a second return spring, 1101708-a second triangular plate, 1101709-a second pawl, 11017010-a third return spring, and 11017011-a four-corner ratchet.

Detailed Description

The invention is further described below with reference to the figures and examples.

Examples

An electrolytic current density control device is shown in figures 1-10 and comprises an outer framework 1, a control display 2, a first cleaning pool 3, a polishing pool 4, a second cleaning pool 5, a portal frame 6, a first slide rail 7, a first electric push rod 8, an anode contact rod 9, a fixed frame 10, a current density control mechanism 11, an anode mud auxiliary separation mechanism 12 and an anode mud collection mechanism 13; the top of the left end of the outer framework 1 is connected with the control display 2 through a bolt; the left part of the top end in the outer framework 1 is welded with the first cleaning pool 3; the middle part of the inner top end of the outer framework 1 is welded with the polishing pool 4, and the top part of the left end of the polishing pool 4 is connected with a first cleaning part; the right part of the inner top end of the outer framework 1 is welded with a second cleaning pool 5, and the top of the left end of the second cleaning pool 5 is connected with a polishing pool 4; the left part and the right part of the top end of the outer framework 1 are both connected with the portal frame 6 through bolts; an anode mud auxiliary separation mechanism 12 is arranged at the top of the inner middle part of the outer framework 1, and the left end of the anode mud auxiliary separation mechanism 12 is connected with the polishing pool 4; the bottom end of the outer framework 1 is provided with an anode mud collecting mechanism 13, and the right part of the top end of the anode mud collecting mechanism 13 is connected with an anode mud auxiliary separating mechanism 12; a current density control mechanism 11 is arranged in the middle of the polishing pool 4, and the bottom end of the current density control mechanism 11 is connected with the outer framework 1; the top of the inner left end and the top of the inner right end of the portal frame 6 are welded with the first slide rail 7; the bottom of the left end and the bottom of the right end in the portal frame 6 are welded with the anode contact rod 9; the right part of the outer surface of the first slide rail 7 is in sliding connection with a first electric push rod 8; the right part of the outer surface of the anode contact rod 9 is provided with a fixed frame 10.

The working principle is as follows: when an electrolytic current density control device is used for polishing metal objects, firstly, an outer framework 1 is fixed on the horizontal ground of an electrolytic polishing workshop, then clear water is added into a first cleaning pool 3 and a second cleaning pool 5, then electrolytic polishing liquid is added into a polishing pool 4, then each mechanism is controlled by a control display 2 to operate, firstly, the metal objects to be subjected to electrolytic polishing are fixed with a fixing frame 10, then the metal objects to be subjected to electrolytic polishing are placed on an anode contact rod 9 and are placed in the second cleaning pool 5, then a first electric push rod 8 is used for electrifying, the fixing frame 10 on the anode contact rod 9 is lifted up through a magnetic belt, then the metal objects to be subjected to electrolytic polishing are moved leftwards on a first slide rail 7 through a first electric push rod 8, then the middle part of the polishing pool 4 is placed downwards, the fixing frame 10 is placed on the anode contact rod 9 again, and then the metal objects to be subjected to polishing are immersed in the electrolytic polishing, then, the current density control mechanism 11 is used for adjusting the density of electrolytic contact pins at two sides according to the surface curved surface shape of the metal object, so that after the current is switched on, the concave part of the metal object is subjected to electrolytic treatment through the high-density side, then the convex part of the metal object is subjected to electrolytic treatment through the side with lower density, the electrolytic polishing speed of the concave part structure is accelerated, meanwhile, the excessive electrolysis of the convex structure is prevented, the polishing loss of the original convex part is large, the metal object is deformed, then the anode mud auxiliary separation mechanism 12 is used for being close to the metal object, the friction is carried out on the metal surface, the anode mud generated on the metal surface is ground, the anode mud which does not fall off in time is timely fallen off, the electrolytic polishing speed is kept, the man-hour consumption is reduced, then the anode mud collection mechanism 13 is used for collecting the anode mud falling into the bottom of, after the electrolytic polishing liquid is discharged, the anode mud is taken out and collected by the anode mud collecting mechanism 13, so that the metal components scattered in the anode mud are recovered, the recycling of resources is enhanced, the curved surface shape of the surface of a metal object is achieved, then the density of the electrolytic contact pins on two sides is adjusted to accelerate the electrolytic polishing speed of the concave structure, meanwhile, the protruding structure is prevented from being excessively electrolyzed, the polishing loss of the original protruding part is overlarge, the metal object is deformed, the anode mud generated on the metal surface is polished, the anode mud which is not timely dropped is timely dropped, the man-hour consumption is reduced, the metal components scattered in the anode mud are recovered, and the purpose of recycling of the resources is enhanced.

The current density control mechanism 11 comprises a second electric push rod 1101, a first sliding plate 1102, a second sliding rail 1103, a first motor 1104, a bidirectional bevel gear 1105, a first bevel gear 1106, a first straight gear 1107, a second straight gear 1108, a bolt bevel gear wheel 1109, a second bevel gear wheel 11010, a first transmission wheel 11011, a first thumb wheel 11012, a second thumb wheel 11013, a third thumb wheel 11014, a third bevel gear wheel 11015, a transmission disc 11016, a right-angle intermittent group 11017, a mounting frame 11018, an annular sliding rail 11019, a cathode contact rod 11020 and a spring discharge differentiator 11021; the right end of the second electric push rod 1101 is connected with the first sliding plate 1102 through a bolt; the bottom end of the first sliding plate 1102 is slidably connected with a second sliding rail 1103; the middle of the top end of the first sliding plate 1102 is connected with a first motor 1104 through a bolt; the middle part of the right end of the first motor 1104 is spliced with a bidirectional bevel gear 1105; a first bevel gear 1106 is arranged at the top of the left end of the bidirectional bevel gear 1105; the top of the right end of the bidirectional bevel gear 1105 is provided with a third bevel gear 11015; the middle part of the top end of the first bevel gear 1106 is inserted into the first straight gear 1107; the left rear part of the first spur gear 1107 is meshed with a second spur gear 1108; the middle of the top end of the second straight gear 1108 is spliced with a bolt bevel gear disc 1109; the front middle part of the top end of the bolt bevel gear disc 1109 is meshed with a second bevel gear 11010; the middle part of the rear end of the second bevel gear 11010 is spliced with a first transmission wheel 11011; the top of the first driving wheel 11011 is in transmission connection with a first thumb wheel 11012 through a belt; the left top of the first thumb wheel 11012 is in transmission connection with a second thumb wheel 11013 through a belt; the right top of the first thumb wheel 11012 is in transmission connection with a third thumb wheel 11014 through a belt; the middle part of the top end of the third bevel gear 11015 is spliced with a transmission disc 11016; the top end of the transmission disc 11016 is in transmission connection with the right-angle intermittent group 11017 through a round pin; the left part of the top end of the right-angle intermittent group 11017 is in transmission connection with the mounting rack 11018, the middle part of the bottom end of the mounting rack 11018 is connected with the first thumb wheel 11012, the bottom of the left end in the mounting rack 11018 is connected with the second thumb wheel 11013, and the bottom of the right end in the mounting rack 11018 is connected with the third thumb wheel 11014; the bottom of the left end and the bottom of the right end of the mounting rack 11018 are connected with an annular sliding rail 11019 in a sliding way; the left middle part of the inner top end and the right middle part of the inner top end of the mounting rack 11018 are welded with a cathode contact rod 11020; the outer surface of the cathode contact rod 11020 is sleeved with a spring discharge differentiator 11021, the middle bottom of the outer surface of the spring discharge differentiator 11021 is connected with a first thumb wheel 11012, the left bottom of the outer surface of the spring discharge differentiator 11021 is connected with a second thumb wheel 11013, and the right bottom of the outer surface of the spring discharge differentiator 11021 is connected with a third thumb wheel 11014; the left part of the bottom end of the second electric push rod 1101 is connected with the outer framework 1; the bottom end of the second sliding rail 1103 is connected with the outer framework 1; the outer surface of the mount 11018 is connected to the polishing pool 4.

When the electrolytic current density is adjusted according to the curved surface state of the metal surface, the second electric push rod 1101 is extended, the first sliding plate 1102 is arranged on the second sliding rail 1103 to slide rightwards, the first motor 1104 is used for driving the two-way bevel gear 1105 to rotate, then the third bevel gear 11015 is meshed to rotate, the third bevel gear 11015 is driven to rotate, then the right-angle intermittent group 11017 is driven to move, then the mounting frame 11018 is driven to rotate in the annular sliding rail 11019, further the balance line of the spring discharge differentiator 11021 and the curved surface normal direction of the metal object is adjusted to be in the same plane, then the second electric push rod 1101 is contracted, the first sliding plate 1102 is pulled to move leftwards, then the two-way bevel gear 1105 is driven to mesh with the first bevel gear 1106, the two-way bevel gear 1105 is driven to rotate by the rotation of the first motor 1104, and the first bevel gear 1106 is meshed to rotate, then the first straight gear 1107 is driven to rotate, the second straight gear 1108 is meshed to rotate, then the bolt bevel gear 1109 is driven to rotate, the bolt bevel gear 1109 is meshed to rotate with the second bevel gear 11010, the first driving wheel 11011 is driven to rotate through the second bevel gear 11010, then the first shifting wheel 11012 is driven to rotate, so that the first shifting wheel 11012 shifts the root of the tip contact pin of the spring discharge differentiator 11021, meanwhile, the second shifting wheel 11013 and the third shifting wheel 11014 are used for assisting in shifting the spring discharge differentiator 11021, the tip contact pin of the spring discharge differentiator 11021 deviates to the concave curved surface side of the metal object, then a power supply is connected for electrolysis, the concave part of the metal object is electrolyzed through the high density side, then the convex part of the metal object is electrolyzed by the side with lower density, the electrolytic polishing speed of the concave structure is accelerated, and the excessive electrolysis of the convex structure is prevented, the polishing loss of the original convex part is larger, and the metal object is deformed.

The auxiliary anode slime separation mechanism 12 comprises a second transmission wheel 1201, a third transmission wheel 1202, a fourth transmission wheel 1203, a fifth transmission wheel 1204, a cam 1205, a sixth transmission wheel 1206, a first screw 1207, a first rotating frame 1208, a third sliding rail 1209, a fixing plate 12010, a sponge plate 12011, a four-step telescopic rod 12012 and a first return spring 12013; the middle part of the left end of the second transmission wheel 1201 is spliced with the third transmission wheel 1202 through a round rod; the middle part of the left end of the third driving wheel 1202 is spliced with the fourth driving wheel 1203 through a round rod; the top end of the third driving wheel 1202 is in driving connection with a sixth driving wheel 1206 through a belt; the top end of the fourth driving wheel 1203 is in driving connection with a fifth driving wheel 1204 through a belt; the middle part of the left end of the fifth driving wheel 1204 is inserted into the cam 1205 through a round rod; the middle part of the left end of the sixth driving wheel 1206 is spliced with the first screw rod 1207; the middle part of the outer surface of the first screw 1207 is rotatably connected with a first rotating frame 1208; the top of the left end and the bottom of the left end of the first rotating frame 1208 are in sliding connection with a third sliding rail 1209; the left end of the third slide rail 1209 is welded with the fixing plate 12010; the top of the left end of the fixing plate 12010 is connected with a sponge plate 12011 through bolts; the top of the right end of the fixed plate 12010 is welded to a fourth-order telescopic rod 12012; the right part of the bottom end of the fourth-order telescopic rod 12012 is welded with the first return spring 12013; the bottom end of the second transmission wheel 1201 is connected with the anode mud collecting mechanism 13 through a belt; the middle part of the right end of the second transmission wheel 1201 is connected with the outer framework 1; the middle part of the left end of the fourth driving wheel 1203 is connected with the polishing pool 4; the middle part of the left end of the polishing pool 4 is connected with the polishing pool 4; the left end of the first screw 1207 is connected with the polishing pool 4; the left top and the left bottom of the outer surface of the first rotating frame 1208 are connected with the polishing pool 4; the right end of the fourth-order telescopic rod 12012 is connected with the polishing pool 4; the bottom end of the first return spring 12013 is connected to the polishing bowl 4.

When the anode slime on the surface of the metal object is deslimed, the third driving wheel 1202 is driven to rotate by the rotation of the second driving wheel 1201, then the sixth driving wheel 1206 is driven to rotate, then the first screw rod 1207 is driven to rotate, the first rotating frame 1208 is moved leftwards by the rotation of the first screw rod 1207, the fixing plate 12010 is pushed leftwards, the fourth-order telescopic rod 12012 extends along with the extension, the fourth driving wheel 1203 is driven to rotate by the third driving wheel 1202, the fifth driving wheel 1204 is driven to rotate by the belt, the cam 1205 is driven to rotate, so that the fourth-order telescopic rod 12012 is repeatedly pressed downwards, the fixing plate 12010 is pressed downwards, when the sponge plate 12011 is close to the surface of the metal object, the first return spring 12013 is used to restore the original height of the fourth-order telescopic rod 12012, and the fixing plate 12010 is driven to return, and the anode slime on the surface is polished, make the positive pole mud of metal surface break away from fast, when retrieving fixed plate 12010, sponge board 12011 leaves the metal surface, and through the continuation rotation of cam 1205, press four steps telescopic link 12012 repeatedly, utilize the shake of sponge board 12011, then positive pole mud on the sponge board 12011 shakes off in polishing pond 4 bottoms, reach and rubs the metal surface, polish the positive pole mud that the metal surface produced, make the positive pole mud that does not in time drop, keep the speed of electrolytic polishing, reduce the effect of man-hour consumption.

The anode sludge collecting mechanism 13 comprises a second motor 1301, a third electric push rod 1302, a third spur gear 1303, a fourth spur gear 1304, a seventh transmission wheel 1305, an eighth transmission wheel 1306, a ninth transmission wheel 1307, a tenth transmission wheel 1308, an eleventh transmission wheel 1309, a fifth spur gear 13010, a sixth spur gear 13011, a second screw 13012, a second rotating frame 13013, a first mesh 13014, a seventh spur gear 13015, a first rectangular rotating frame 13016, a third rotating frame 13017, a second mesh 13018, an eighth spur gear 13019 and a second rectangular rotating frame 13020; the bottom end of the second motor 1301 is welded with the third electric push rod 1302; the middle part of the left end of the second motor 1301 is inserted into the third straight gear 1303; a fourth straight gear 1304 is arranged at the rear part of the top end of the third straight gear 1303; a sixth straight gear 13011 is arranged at the front part of the bottom end of the third straight gear 1303; the middle part of the right end of the fourth straight gear 1304 is spliced with a seventh transmission wheel 1305; the middle part of the right end of the seventh driving wheel 1305 is spliced with the eighth driving wheel 1306; the top end of the eighth transmission wheel 1306 is spliced with the ninth transmission wheel 1307 through a belt; the left end of the ninth driving wheel 1307 is spliced with the tenth driving wheel 1308 through a round rod; the bottom of the tenth transmission wheel 1308 is in transmission connection with an eleventh transmission wheel 1309 through a belt; the middle part of the right end of the eleventh transmission wheel 1309 is spliced with a fifth straight gear 13010; the middle part of the left end of the sixth spur gear 13011 is spliced with the second screw mandrel 13012; the right middle part of the outer surface of the second screw rod 13012 is rotatably connected with a second rotating rack 13013; the top end of the second rotating frame 13013 is rotatably connected with the first net plate 13014; the middle part of the right end of the first screen 13014 is spliced with a seventh spur gear 13015; the right part of the outer surface of the first screen 13014 is in sliding connection with a first rectangular rotating frame 13016; the left middle part of the outer surface of the second screw rod 13012 is rotatably connected with a third rotating frame 13017; the top end of the third rotating frame 13017 is rotatably connected with the second net plate 13018; the middle part of the left end of the second screen 13018 is spliced with an eighth spur gear 13019; the left part of the outer surface of the eighth spur gear 13019 is in sliding connection with a second rectangular rotating frame 13020; the bottom end of the third electric push rod 1302 is connected with the outer framework 1; the top end of the seventh transmission wheel 1305 is connected with the second transmission wheel 1201 through a belt; the middle part of the right end of the eighth driving wheel 1306 is connected with the outer framework 1; the middle part of the right end of the ninth transmission wheel 1307 is connected with the outer framework 1; the middle part of the left end of the ninth transmission wheel 1307 is connected with the polishing pool 4 through a round rod; the right part of the outer surface of the first screen 13014 is connected with a polishing pool 4; the middle part of the left end of the first rectangular rotating frame 13016 is connected with the polishing pool 4; the left part of the outer surface of the second screen 13018 is connected with a polishing pool 4; the middle of the right end of the second rectangular rotary frame 13020 is connected with the polishing bath 4.

When anode mud at the bottom of the polishing pool 4 is cleaned and collected, the third straight gear 1303 is driven to rotate by the rotation of the second motor 1301, then the third electric push rod 1302 is contracted to enable the third straight gear 1303 to be meshed with the sixth straight gear 13011, then the second screw 13012 is driven to rotate, then the second rotating rack 13013 and the third rotating rack 13017 are driven to move towards two far sides respectively, then the first screen 13014 is drawn out towards the right, the left end of the first screen 13014 is arranged in the first rectangular rotating frame 13016, meanwhile, the seventh straight gear 13015 is meshed with the fourth straight gear 1304, and similarly, the second screen 13018 is drawn out towards the left, then the right end of the second screen 13018 is arranged in the second rectangular rotating frame 13020, meanwhile, the eighth straight gear 13019 is meshed with the fifth straight gear 13010, the third electric push rod 1302 is pushed out, then the third straight gear 1303 is meshed with the fourth straight gear 1304, then the third straight gear 1303 is driven to rotate by the second motor 1303, the fourth straight gear 1304 is driven to rotate through meshing, the eighth transmission gear 1306 drives the ninth transmission gear 1307 to rotate, meanwhile, the ninth transmission gear 1307 drives the tenth transmission gear 1308 to rotate, then, the eleventh transmission gear 1309 is driven to rotate, meanwhile, the fifth straight gear 13010 is driven to rotate, then, the fourth straight gear 1304 is meshed with the seventh straight gear 13015 to drive the first screen 13014 to turn over, the first rectangular rotating frame 13016 turns over along with the turning over, meanwhile, the fifth straight gear 13010 is meshed with the eighth straight gear 13019 to drive the second screen 13018 to turn over, the second rectangular rotating frame 13020 turns over along with the turning over, then, the deposit is led into a collecting box at the bottom of the outer framework 1 through the polishing pool 4, the metal components scattered in the anode mud are recycled, and the purpose of recycling resources is enhanced.

The right-angle intermittent group 11017 comprises a first transmission rod 1101701, a limit sleeve 1101702, a second transmission rod 1101703, a third transmission rod 1101704, a first triangular plate 1101705, a first pawl 1101706, a second return spring 1101707, a second triangular plate 1101708, a second pawl 1101709, a third return spring 11017010 and a four-corner ratchet 11017011; the left part of the outer surface of the first transmission rod 1101701 is in sliding connection with the limit sleeve 1101702; the left end of the first transmission rod 1101701 is hinged with the second transmission rod 1101703; the left end of the first transmission rod 1101701 is hinged with the third transmission rod 1101704; the left bottom of the rear end of the second transmission rod 1101703 is in transmission connection with the first triangular plate 1101705; the left top of the rear end of the third driving rod 1101704 is in driving connection with the second triangular plate 1101708, and the right bottom of the front end of the second triangular plate 1101708 is connected with the first triangular plate 1101705; the left bottom of the rear end of the first triangle 1101705 is rotatably connected with the first pawl 1101706; the front middle part and the bottom part of the first triangular plate 1101705 are connected with a second return spring 1101707, and the bottom end of the second return spring 1101707 is connected with a first pawl 1101706; the left top of the rear end of the second triangle 1101708 is rotatably connected with a second pawl 1101709; the left middle of the front end of the second triangle 1101708 is connected with the third return spring 11017010, and the left end of the third return spring 11017010 is connected with the second pawl 1101709; the right bottom of the rear end of the second triangle 1101708 is rotatably connected with the four-corner ratchet wheel 11017011, the middle of the bottom end of the second triangle is connected with the first pawl 1101706, and the left of the top end of the second triangle is connected with the second pawl 1101709; the right part of the front end of the first transmission rod 1101701 is connected with a transmission disc 11016; the bottom end of the limit sleeve 1101702 is connected with the outer framework 1; the central portion of the top end of the four corner ratchet 11017011 is connected to a mounting bracket 11018.

The right-angle intermittent group 11017 is used for intermittent transmission, when the mounting frame 11018 is driven to rotate, the first transmission rod 1101701 is pushed leftwards, then the second transmission rod 1101703 and the third transmission rod 1101704 are respectively pushed leftwards, the second triangular plate 1101708 is utilized to push the second pawl 1101709, then the four-corner ratchet wheel 11017011 is pushed to rotate by a right angle through the second pawl 1101709, meanwhile, the second return spring 1101707 tensions the first pawl 1101706, the first pawl 1101706 is made to cling to the four-corner ratchet wheel 11017011, the next group of teeth are clamped through the first pawl 1101706, then the first transmission rod 1101701 is pushed leftwards, the four-corner ratchet wheel 11017011 is pushed to rotate through the first pawl 1101706, meanwhile, the second pawl 1101709 is made to cling to the four-corner ratchet wheel 11017011, and therefore, the mounting frame 11018 is driven to perform right-angle intermittent motion, and adjustment of the plane where the spring discharge differentiator 11021 is located is achieved.

8 bottoms of first electric putter are provided with the electromagnetism piece, and mount 10 tops are provided with the electromagnetism piece and utilize the electromagnetism piece to get mount 10 and put, utilize the electromagnetism assimilation simultaneously, make metal object can not produce and rock in mount 10 transfer process.

The spring discharge differentiator 11021 is set as a staggered combination structure of the tip contact pins and the springs, and the contact pin density is utilized to have the defect of current density during electrolysis, and meanwhile, the springs are utilized to enable the current density distribution of one side to be always kept uniform and facilitate adjustment.

The four corners of the four-corner ratchet 11017011 are each provided with a triangular projection and combined in a windmill shape, and the right-angle intermittent motion of the four-corner ratchet 11017011 is realized by the urging of the first pawl 1101706 and the second pawl 1101709.

Although the present disclosure has been described in detail with reference to the exemplary embodiments, the present disclosure is not limited thereto, and it will be apparent to those skilled in the art that various modifications and changes can be made thereto without departing from the scope of the present disclosure.

Claims

1. An electrolytic current density control device comprises an outer framework (1), a control display (2), a first cleaning pool (3), a polishing pool (4), a second cleaning pool (5), a portal frame (6), a first sliding rail (7), a first electric push rod (8), an anode contact rod (9) and a fixing frame (10), and is characterized by further comprising a current density control mechanism (11), an anode mud auxiliary separation mechanism (12) and an anode mud collection mechanism (13); the top of the left end of the outer framework (1) is connected with the control display (2) through a bolt; the left part of the top end in the outer framework (1) is welded with the first cleaning pool (3); the middle part of the inner top end of the outer framework (1) is welded with the polishing pool (4), and the top of the left end of the polishing pool (4) is connected with a first cleaning device; the right part of the top end in the outer framework (1) is welded with a second cleaning pool (5), and the top of the left end of the second cleaning pool (5) is connected with a polishing pool (4); the left part and the right part of the top end of the outer framework (1) are both connected with the portal frame (6) through bolts; an anode mud auxiliary separation mechanism (12) is arranged at the middle top part in the outer framework (1), and the left end of the anode mud auxiliary separation mechanism (12) is connected with the polishing pool (4); an anode mud collecting mechanism (13) is arranged at the bottom end of the outer framework (1), and the right part of the top end of the anode mud collecting mechanism (13) is connected with an anode mud auxiliary separating mechanism (12); a current density control mechanism (11) is arranged in the middle of the polishing pool (4), and the bottom end of the current density control mechanism (11) is connected with the outer framework (1); the top of the inner left end and the top of the inner right end of the portal frame (6) are welded with the first sliding rail (7); the bottom of the left end and the bottom of the right end in the portal frame (6) are welded with the anode contact rod (9); the right part of the outer surface of the first sliding rail (7) is in sliding connection with a first electric push rod (8); the right part of the outer surface of the anode contact rod (9) is provided with a fixed frame (10).

2. The electrolytic current density control device according to claim 1, wherein the current density control mechanism (11) comprises a second electric push rod (1101), a first sliding plate (1102), a second sliding rail (1103), a first motor (1104), a bidirectional bevel gear (1105), a first bevel gear (1106), a first straight gear (1107), a second straight gear (1108), a bolt bevel gear plate (1109), a second bevel gear (11010), a first driving wheel (11011), a first thumb wheel (11012), a second thumb wheel (11013), a third thumb wheel (11014), a third bevel gear (11015), a driving disk (11016), a right-angle intermittent group (11017), a mounting frame (11018), an annular sliding rail (11019), a cathode contact rod (11020) and a spring discharge differentiator (11021); the right end of the second electric push rod (1101) is connected with the first sliding plate (1102) through a bolt; the bottom end of the first sliding plate (1102) is in sliding connection with the second sliding rail (1103); the middle part of the top end of the first sliding plate (1102) is connected with a first motor (1104) through a bolt; the middle part of the right end of the first motor (1104) is spliced with the bidirectional bevel gear (1105); a first bevel gear (1106) is arranged at the top of the left end of the bidirectional bevel gear (1105); a third bevel gear (11015) is arranged at the top of the right end of the bidirectional bevel gear (1105); the middle part of the top end of the first bevel gear (1106) is inserted into the first straight gear (1107); the left rear part of the first straight gear (1107) is meshed with a second straight gear (1108); the middle part of the top end of the second straight gear (1108) is spliced with a bolt conical fluted disc (1109); the front middle part of the top end of the bolt conical fluted disc (1109) is meshed with a second bevel gear (11010); the middle part of the rear end of the second bevel gear (11010) is spliced with the first transmission wheel (11011); the top of the first driving wheel (11011) is in transmission connection with a first thumb wheel (11012) through a belt; the left top of the first thumb wheel (11012) is in transmission connection with the second thumb wheel (11013) through a belt; the right top of the first thumb wheel (11012) is in transmission connection with a third thumb wheel (11014) through a belt; the middle part of the top end of the third bevel gear (11015) is spliced with the transmission disc (11016); the top end of the transmission disc (11016) is in transmission connection with the right-angle intermittent group (11017) through a round pin; the left part of the top end of the right-angle intermittent group (11017) is in transmission connection with a mounting rack (11018), the middle part of the bottom end of the mounting rack (11018) is connected with a first thumb wheel (11012), the bottom of the inner left end of the mounting rack (11018) is connected with a second thumb wheel (11013), and the bottom of the inner right end of the mounting rack (11018) is connected with a third thumb wheel (11014); the bottom of the left end and the bottom of the right end of the mounting rack (11018) are both in sliding connection with an annular sliding rail (11019); the left middle part of the inner top end and the right middle part of the inner top end of the mounting rack (11018) are welded with the cathode contact rod (11020); the outer surface of the cathode contact rod (11020) is sleeved with a spring discharge differentiator (11021), the middle bottom of the outer surface of the spring discharge differentiator (11021) is connected with a first thumb wheel (11012), the left bottom of the outer surface of the spring discharge differentiator (11021) is connected with a second thumb wheel (11013), and the right bottom of the outer surface of the spring discharge differentiator (11021) is connected with a third thumb wheel (11014); the left part of the bottom end of the second electric push rod (1101) is connected with the outer framework (1); the bottom end of the second sliding rail (1103) is connected with the outer framework (1); the outer surface of the mounting rack (11018) is connected with the polishing pool (4).

3. An electrolytic current density control device according to claim 2, wherein the anode slime auxiliary separation mechanism (12) comprises a second transmission wheel (1201), a third transmission wheel (1202), a fourth transmission wheel (1203), a fifth transmission wheel (1204), a cam (1205), a sixth transmission wheel (1206), a first screw rod (1207), a first rotating frame (1208), a third slide rail (1209), a fixed plate (12010), a sponge plate (12011), a fourth-step telescopic rod (12012) and a first return spring (12013); the middle part of the left end of the second transmission wheel (1201) is spliced with the third transmission wheel (1202) through a round rod; the middle part of the left end of the third driving wheel (1202) is spliced with the fourth driving wheel (1203) through a round bar; the top end of the third driving wheel (1202) is in transmission connection with a sixth driving wheel (1206) through a belt; the top end of the fourth driving wheel (1203) is in transmission connection with a fifth driving wheel (1204) through a belt; the middle part of the left end of the fifth driving wheel (1204) is inserted into the cam (1205) through a round rod; the middle part of the left end of a sixth driving wheel (1206) is spliced with a first screw rod (1207); the middle part of the outer surface of the first screw rod (1207) is rotatably connected with a first rotating frame (1208); the top of the left end and the bottom of the left end of the first rotating frame (1208) are in sliding connection with a third sliding rail (1209); the left end of the third sliding rail (1209) is welded with the fixing plate (12010); the top of the left end of the fixing plate (12010) is connected with a sponge plate (12011) through a bolt; the top of the right end of the fixed plate (12010) is welded with a four-step telescopic rod (12012); the right part of the bottom end of the four-step telescopic rod (12012) is welded with the first return spring (12013); the bottom end of the second transmission wheel (1201) is connected with the anode mud collecting mechanism (13) through a belt; the middle part of the right end of the second transmission wheel (1201) is connected with the outer framework (1); the middle part of the left end of a fourth driving wheel (1203) is connected with the polishing pool (4); the middle part of the left end of the polishing pool (4) is connected with the polishing pool (4); the left end of the first screw rod (1207) is connected with the polishing pool (4); the left top part of the outer surface and the left bottom part of the outer surface of the first rotating frame (1208) are connected with the polishing pool (4); the right end of the fourth-order telescopic rod (12012) is connected with the polishing pool (4); the bottom end of the first return spring (12013) is connected with the polishing pool (4).

4. An electrolysis current density control device according to claim 3, wherein the anode sludge collecting mechanism (13) comprises a second motor (1301), a third electric push rod (1302), a third spur gear (1303), a fourth spur gear (1304), a seventh transmission gear (1305), an eighth transmission gear (1306), a ninth transmission gear (1307), a tenth transmission gear (1308), an eleventh transmission gear (1309), a fifth spur gear (13010), a sixth spur gear (13011), a second screw (13012), a second rotating frame (13013), a first mesh plate (13014), a seventh spur gear (13015), a first rectangular rotating frame (13016), a third rotating frame (13017), a second mesh plate (18), an eighth spur gear (13019) and a second rectangular rotating frame (13020); the bottom end of the second motor (1301) is welded with the third electric push rod (1302); the middle part of the left end of the second motor (1301) is inserted into the third straight gear (1303); a fourth straight gear (1304) is arranged at the rear part of the top end of the third straight gear (1303); a sixth straight gear (13011) is arranged at the front part of the bottom end of the third straight gear (1303); the middle part of the right end of the fourth straight gear (1304) is spliced with a seventh transmission wheel (1305); the middle part of the right end of the seventh driving wheel (1305) is spliced with the eighth driving wheel (1306); the top end of the eighth transmission wheel (1306) is spliced with the ninth transmission wheel (1307) through a belt; the left end of the ninth driving wheel (1307) is spliced with the tenth driving wheel (1308) through a round rod; the bottom of the tenth transmission wheel (1308) is in transmission connection with an eleventh transmission wheel (1309) through a belt; the middle part of the right end of the eleventh transmission wheel (1309) is spliced with a fifth straight gear (13010); the middle part of the left end of the sixth straight gear (13011) is spliced with the second screw rod (13012); the right middle part of the outer surface of the second screw rod (13012) is rotatably connected with a second rotating frame (13013); the top end of the second rotating frame (13013) is rotatably connected with the first screen plate (13014); the middle part of the right end of the first screen plate (13014) is spliced with a seventh straight gear (13015); the right part of the outer surface of the first screen plate (13014) is in sliding connection with the first rectangular rotating frame (13016); the left middle part of the outer surface of the second screw rod (13012) is rotatably connected with a third rotating frame (13017); the top end of the third rotating frame (13017) is rotatably connected with the second screen plate (13018); the middle part of the left end of the second screen plate (13018) is spliced with an eighth straight gear (13019); the left part of the outer surface of the eighth straight gear (13019) is in sliding connection with the second rectangular rotating frame (13020); the bottom end of the third electric push rod (1302) is connected with the outer framework (1); the top end of the seventh transmission wheel (1305) is connected with the second transmission wheel (1201) through a belt; the middle part of the right end of the eighth transmission wheel (1306) is connected with the outer framework (1); the middle part of the right end of the ninth transmission wheel (1307) is connected with the outer framework (1); the middle part of the left end of a ninth transmission wheel (1307) is connected with the polishing pool (4) through a round rod; the right part of the outer surface of the first screen plate (13014) is connected with the polishing pool (4); the middle part of the left end of the first rectangular rotating frame (13016) is connected with the polishing pool (4); the left part of the outer surface of the second screen plate (13018) is connected with the polishing pool (4); the middle part of the right end of the second rectangular rotating frame (13020) is connected with the polishing pool (4).

5. An electrolytic current density control device according to claim 4, characterized in that the right angle intermittent group (11017) comprises a first transmission rod (1101701), a limit sleeve (1101702), a second transmission rod (1101703), a third transmission rod (1101704), a first triangular plate (1101705), a first pawl (1101706), a second return spring (1101707), a second triangular plate (1101708), a second pawl (1101709), a third return spring (11017010) and a four-angle ratchet (11017011); the left part of the outer surface of the first transmission rod (1101701) is in sliding connection with the limit sleeve (1101702); the left end of the first transmission rod (1101701) is hinged with the second transmission rod (1101703); the left end of the first transmission rod (1101701) is hinged with the third transmission rod (1101704); the left bottom of the rear end of the second transmission rod (1101703) is in transmission connection with the first triangular plate (1101705); the left top of the rear end of the third transmission rod (1101704) is in transmission connection with the second triangular plate (1101708), and the right bottom of the front end of the second triangular plate (1101708) is connected with the first triangular plate (1101705); the left bottom of the rear end of the first triangle (1101705) is rotationally connected with the first pawl (1101706); the middle part of the front end and the bottom of the first triangular plate (1101705) is connected with a second return spring (1101707), and the bottom end of the second return spring (1101707) is connected with a first pawl (1101706); the left top of the rear end of the second triangular plate (1101708) is rotationally connected with a second pawl (1101709); the left middle part of the front end of the second triangle (1101708) is connected with a third return spring (11017010), and the left end of the third return spring (11017010) is connected with a second pawl (1101709); the right bottom of the rear end of the second triangular plate (1101708) is rotatably connected with a four-corner ratchet wheel (11017011), the middle of the bottom end of the second triangular plate is connected with a first pawl (1101706), and the left part of the top end of the second triangular plate is connected with a second pawl (1101709); the right part of the front end of the first transmission rod (1101701) is connected with a transmission disc (11016); the bottom end of the limiting sleeve (1101702) is connected with the outer framework (1); the middle part of the top end of the four-corner ratchet wheel (11017011) is connected with a mounting rack (11018).

6. An electrolytic current density control device according to claim 5, characterized in that the bottom end of the first electric push rod (8) is provided with an electromagnetic block, and the top end of the fixed frame (10) is provided with an electromagnetic block.

7. An electrolytic current density control device according to claim 6, wherein the spring discharge differentiator (11021) is provided as an interleaved combination of tip contact pins and springs.

8. An electrolytic current density control device according to claim 7, wherein the four corner ratchets (11017011) are each provided with a triangular projection at each of the four corners and are combined in a windmill shape.