CN114951211B - Processing system and method for conductive ink - Google Patents

Abstract

The invention relates to the technical field of printing ink, in particular to a processing system and a processing method of conductive printing ink. The invention can thoroughly clean the waste copper wires and recycle the waste copper wires. The processing system of the conductive ink comprises an H-shaped frame, wherein two ends of the H-shaped frame are respectively connected with a guide frame in a matched mode, a circular ring I and a circular ring II are respectively arranged on the two guide frames, and a fixing piece for clamping a copper wire is also arranged on the H-shaped frame; the method for processing the conductive ink comprises the following steps: a: inserting waste copper wires into the corresponding two sleeves to fix, wherein the copper wires are positioned between the circular ring I and the circular ring II; b: polishing the oxide layer on the surface of the copper wire by the circular ring I and the circular ring II; c: the ring I and the ring II are close to each other to roll the copper wire, and the copper wire is extruded to deform; d: grinding the clean copper wire after removing the oxide layer into powder to obtain conductive filler, and uniformly mixing the conductive filler, an adhesive, a solvent and an additive to obtain the conductive ink.

Description

Processing system and method for conductive ink

Technical Field

The invention relates to the technical field of printing ink, in particular to a processing system and a processing method of conductive printing ink.

Background

The printing ink made of conductive materials has a certain conductive property, can be used for printing conductive points or conductive circuits, is oxidized when being overloaded or exposed in the air for a long time, and is rusted in a wet environment, so that a large number of waste copper wires are inevitably generated, the copper wires have high recovery value, and the waste copper wires can be used for processing the conductive printing ink after being treated, thereby saving the consumption of copper materials in principle.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention provides a processing system and a processing method of conductive ink.

The technical scheme adopted for solving the technical problems is as follows:

the processing system of the conductive ink comprises an H-shaped frame, wherein two ends of the H-shaped frame are respectively connected with a guide frame in a matched mode, a circular ring I and a circular ring II are respectively arranged on the two guide frames, and a fixing piece for clamping a copper wire is also arranged on the H-shaped frame; the copper wire can be extruded by the circular ring I and the circular ring II which are matched up and down, and the circular ring I and the circular ring II are respectively provided with the scraper I and the scraper II which can scrape the oxide layer.

Annular grooves are formed in the two ends of the circular ring I respectively, and the two ends of the circular ring II are welded and connected with convex rings capable of being embedded into the annular grooves respectively.

The connecting sleeve I and the connecting sleeve II are respectively welded on the circular ring I and the circular ring II, the connecting sleeve I and the connecting sleeve II are respectively connected to the two guide frames in a sliding mode, connecting plates are respectively welded on the connecting sleeve I and the connecting sleeve II, and an electric push rod I is fixedly connected between the connecting plates and the guide frames.

A method of processing conductive ink by a conductive ink processing system, the method comprising the steps of:

a: inserting waste copper wires into the corresponding two sleeves to fix, wherein the copper wires are positioned between the circular ring I and the circular ring II;

b: the ring I and the ring II are controlled to rotate in opposite directions, and an oxide layer on the surface of the copper wire is polished;

c: the rotating circular ring I and the rotating circular ring II are controlled to be close to each other to roll the copper wire, and the copper wire is extruded to deform;

d: grinding the clean copper wire after removing the oxide layer into powder to obtain conductive filler, and uniformly mixing the conductive filler, an adhesive, a solvent and an additive to obtain the conductive ink.

Drawings

The invention will be described in further detail with reference to the accompanying drawings and detailed description.

FIG. 1 is a flow chart of a method of processing conductive ink;

FIG. 2 is a schematic structural view of a ring I and a ring II;

FIG. 3 is a schematic structural view of a fixing member;

FIG. 4 is a schematic structural view of a guide frame;

FIG. 5 is a schematic view of the structure of the ring I;

FIG. 6 is a schematic view of the structure of the ring II;

FIG. 7 is a schematic view of the structure of the drive shaft rack;

FIG. 8 is a schematic structural view of a sleeve;

FIGS. 9 and 10 are schematic structural diagrams of a conductive ink processing system;

Detailed Description

As shown in fig. 2 to 6:

the waste copper wires are arranged on the fixing piece to be fixed, the copper wires are positioned between the circular ring I301 and the circular ring II 401, the circular ring I301 and the circular ring II 401 are controlled to be in contact with the surfaces of the copper wires, the circular ring I301 and the circular ring II 401 are controlled to rotate in opposite directions, the oxide layers on the surfaces of the copper wires are polished in a rolling mode, the oxide layers or stains on the surfaces of the copper wires are polished, the copper wires are controlled to rotate, the whole circumferential surfaces of the copper wires can be polished, when the circular ring I301 and the circular ring II 401 move along the direction in which the copper wires are arranged, the oxide layers on the surfaces of the whole copper wires can be polished, clean copper wires are obtained after the oxide layers are removed, and further the waste copper wires are convenient to recycle after being processed, and conductive ink is prepared by grinding powder;

when the circular ring I301 and the circular ring II 401 are mutually close to each other and move, the cylindrical copper wire can be extruded, the copper wire is deformed and flattened under the extrusion force, meanwhile, the oxidation layer on the surface of the copper wire is extruded and deformed, and after the oxidation layer is extruded and cracked, the oxidation layer can be easily separated from the surface of the copper wire, so that the oxidation layer which cannot be polished and ground off can be stripped from the copper wire in an extrusion mode;

when the copper wire is flattened, the copper wire is controlled to rotate for a certain angle, and then the copper wire is extruded again, so that the other part on the circumferential surface of the copper wire is flattened again, the circumferential surface of the whole copper wire can be extruded by controlling the rotation of the copper wire, and further, the oxide layer on the whole circumferential surface can be extruded, crushed and stripped;

a plurality of scrapers I304 are uniformly distributed on the arc-shaped end face of the upper half part of the circular ring I301, and a plurality of scrapers II 404 are uniformly distributed on the arc-shaped end face of the lower half part of the circular ring II 401; when the finishing surfaces on the circular ring I301 and the circular ring II 401 are contacted with the copper wire, the circular ring I301 and the circular ring II 401 are close to each other to flatten the copper wire, and when the scraper I304 and the scraper II 404 on the circular ring I301 and the circular ring II 401 are contacted with the copper wire, the circular ring I301 and the circular ring II 401 rotate, so that the annular groove 303 and the scraper I304 can scrape an oxide layer which is more intractable on the surface of the copper wire.

As shown in fig. 5 to 6:

the circular ring I301 and the circular ring II 401 can synchronously move back and forth on the two guide frames 205, when the copper wire is in a state that the copper wire is loose and is not tensioned, the circular ring I301 and the circular ring II 401 drive the copper wire contacted with the copper wire to be stretched in the front-back direction, the bent copper wire stretched in the front-back direction can further promote the oxidation layer on the copper wire to be extruded and deformed, and the separation of the oxidation layer and the copper wire is promoted;

the copper wire is located between the two convex rings 403, when the ring I301 and the ring II 401 approach each other, the surfaces of the ring I301 and the ring II 401 are in contact with the copper wire, and the convex rings 403 are embedded into the annular groove 303, so that the copper wire is limited in the space formed between the ring I301, the ring II 401 and the two convex rings 403, and therefore, when the ring I301 and the ring II 401 synchronously move forwards or backwards on the two guide frames 205, the copper wire cannot be separated from the space between the ring I301 and the ring II 401.

As shown in fig. 2 and 4 to 6:

the circular ring I301 is provided with a plurality of connecting sleeves I302 on the circular ring I301 which are all connected to the guide frame 205 at the upper end in a sliding way, and each connecting sleeve I302 is fixedly connected with the connecting plate 209 at the upper end; the number of the circular rings II 401 is multiple, the connecting sleeves II 402 on the circular rings II 401 are all connected to the guide frame 205 at the lower end in a sliding way, each connecting sleeve II 402 is fixedly connected with the connecting plate 209 at the lower end, and the circular rings I301 and the circular rings II 401 are vertically corresponding to each other, so that oxide layer removal treatment can be carried out on a plurality of copper wires at the same time;

the electric putter I starts and drives two connecting plates 209 and reciprocate in step, and two connecting plates 209 drive respectively and a plurality of rings I301 and a plurality of rings II 401 that are connected with it and reciprocate in step, and then synchronous drive many copper lines carry out synchronous stretching in the fore-and-aft direction.

As shown in fig. 4:

the two guide frames 205 are respectively arranged on the two shaft frames 203, and the two shaft frames 203 are respectively connected with the two ends of the H-shaped frame 202 in a sliding way;

the two shaft brackets 203 are mutually close to or far away from and slide on the H-shaped bracket 202, so that the circular ring I301 and the circular ring II 401 are driven to move towards the direction close to the copper wire or move towards the direction far away from the copper wire, and the copper wire is convenient to insert and take out.

Further:

the shaft bracket 203 is fixedly connected with a gear motor 204 through a bolt, the guide frames 205 are fixedly connected to an output shaft of the gear motor 204 through bolts, when the two gear motors 204 rotate, the two guide frames 205 are respectively driven to rotate, and the two guide frames 205 respectively drive the circular ring I301 and the circular ring II 401 to rotate in opposite directions through the connecting sleeve I302 and the connecting sleeve II 402, so that copper wires are polished and rolled.

As shown in fig. 7:

the two shaft brackets 203 are respectively connected with two ends of a screw rod 207 in a threaded manner, the screw rod 207 is fixedly connected to an output shaft of a driving motor through a coupler, the driving motor is fixedly connected to a bracket 206 through a bolt, the bracket 206 is arranged on the H-shaped bracket 202, a guide rod 208 is welded on the bracket 206, and the two shaft brackets 203 are vertically and slidably connected with the guide rod 208;

the driving motor is started to drive the screw 207 to rotate, and then drives the shaft brackets 203 to mutually approach or separate from the guide rods 208 to slide, so that the circular ring I301 and the circular ring II 401 are driven to simultaneously move in the direction approaching or separating from the copper wire.

Further:

the bracket 206 is vertically and slidably connected to the H-shaped frame 202, an electric push rod II is arranged between the bracket 206 and the H-shaped frame 202, when the copper wire is in a state that the copper wire is not tensioned, the electric push rod II is started to drive the bracket 206 to slide on the H-shaped frame 202, so that the two shaft frames 203 are synchronously driven to move up and down, the two shaft frames 203 drive the circular ring I301 and the circular ring II 401 to synchronously move up and down, the circular ring I301 and the circular ring II 401 drive the copper wire contacted with the circular ring I301 and the circular ring II to move up and down, the copper wire is further driven to stretch in the vertical direction, the copper wire stretched and bent in the vertical direction can further promote the oxidation layer on the copper wire to be extruded and deformed, and the oxidation layer and the copper wire separation are promoted.

As shown in fig. 3 and 8:

the H-shaped frame 202 is fixedly connected to the sliding sleeve seat 201, the sliding sleeve seat 201 is slidably connected to the cross beam 101, an electric push rod III is arranged between the sliding sleeve seat 201 and the cross beam 101, the electric push rod III is started to drive the sliding sleeve seat 201 to slide on the cross beam 101, so that the circular ring I301 and the circular ring II 401 are driven to move left and right, and further the whole copper wire is subjected to oxide layer stripping treatment operation.

As shown in fig. 8:

the fixing piece comprises adjusting rods 102 which are connected to the two ends of the cross beam 101 in a sliding mode, an electric push rod IV is arranged between the cross beam 101 and the adjusting rods 102, the two adjusting rods 102 are connected with a sleeve 103 in a limiting rotation mode, locking screws are connected to the sleeve 103 in a threaded mode, rubber sheets are adhered to the inside of the sleeve 103, and friction force between the sleeve and copper wires is increased;

the waste copper wire is penetrated from the left sleeve 103, the copper wire penetrates through the space between the circular ring I301 and the circular ring II 401 and then penetrates out from the right sleeve 103, and the copper wire is tightly pressed against the copper wire by screwing the screw, so that the copper wire is fixed between the two sleeves 103;

the two adjusting rods 102 are respectively and rotatably connected with a plurality of sleeves 103, and the sleeves 103 positioned on two sides are correspondingly arranged, so that a plurality of copper wires can be fixed and processed;

the electric push rod IV is started to drive the two adjusting rods 102 to move close to or away from each other, so that the copper wires can be straightened, the copper wires can be polished conveniently, or the copper wires are in a loose state, and the copper wires can be stretched in the vertical direction and the front-back direction conveniently;

the fixing piece further comprises a gear 104 and a rack 105, the gear 104 is connected to the sleeve 103 in a key manner, the gear 104 is in meshed transmission connection with the rack 105, the rack 105 is slidably connected to the adjusting rod 102, an electric push rod V is arranged between the rack 105 and the adjusting rod 102, the electric push rod V starts to drive the rack 105 to reciprocate, the rack 105 drives the gear 104 to rotate, the sleeve 103 is driven to rotate, and the sleeve 103 drives copper wires in the sleeve to rotate, so that the circumferential surface of the whole copper wires is processed.

A method of processing conductive ink by a conductive ink processing system, the method comprising the steps of:

a: inserting waste copper wires into the corresponding two sleeves 103 for fixing, wherein the copper wires are positioned between the circular ring I301 and the circular ring II 401;

b: the ring I301 and the ring II 401 are controlled to rotate in opposite directions, and an oxide layer on the surface of the copper wire is polished;

c: the rotating circular ring I301 and the circular ring II 401 are controlled to be close to each other to roll the copper wire, and the copper wire is extruded to deform;

d: grinding the clean copper wire after removing the oxide layer into powder to obtain conductive filler, and uniformly mixing the conductive filler, an adhesive, a solvent and an additive to obtain the conductive ink.

Claims (4)

1. A system for processing conductive ink, characterized in that: the copper wire clamping device comprises an H-shaped frame (202), wherein two ends of the H-shaped frame (202) are respectively connected with a guide frame (205) in a matched mode, a circular ring I (301) and a circular ring II (401) are respectively arranged on the two guide frames (205), and a fixing piece for clamping a copper wire is further arranged on the H-shaped frame (202); the copper wire can be extruded by the circular ring I (301) and the circular ring II (401) which are matched up and down, and the circular ring I (301) and the circular ring II (401) are respectively provided with a scraper I (304) and a scraper II (404) which can scrape an oxide layer;

connecting sleeves I (302) and II (402) are fixedly connected to the circular ring I (301) and the circular ring II (401) respectively, the connecting sleeves I (302) and II (402) are respectively and slidably connected to the two guide frames (205), connecting plates (209) are fixedly connected to the connecting sleeves I (302) and II (402) respectively, and an electric push rod I is arranged between the connecting plates (209) and the guide frames (205); the electric push rod I starts to drive the two connecting plates (209) to synchronously move back and forth, and the two connecting plates (209) respectively drive a plurality of rings I (301) and a plurality of rings II (401) connected with the connecting plates to synchronously move back and forth, so that a plurality of copper wires are synchronously driven to synchronously stretch in the front-back direction;

the two guide frames (205) are respectively arranged on the two shaft frames (203), and the two shaft frames (203) are respectively connected to the two ends of the H-shaped frame (202) in a sliding way;

a speed reduction motor (204) is fixedly connected to the shaft bracket (203), and a guide frame (205) is fixedly connected to an output shaft of the speed reduction motor (204);

the two shaft brackets (203) are respectively connected with two ends of a screw rod (207) in a threaded manner, the screw rod (207) is connected with a bracket (206), the bracket (206) is arranged on the H-shaped bracket (202), a guide rod (208) is fixedly connected on the bracket (206), and the two shaft brackets (203) are both movably connected with the guide rod (208);

the bracket (206) is connected to the H-shaped frame (202) in a sliding way, and an electric push rod II is arranged between the bracket (206) and the H-shaped frame (202); when the copper wire is in a state that the relaxation is not tensioned, the circular ring I (301) and the circular ring II (401) drive the copper wire contacted with the copper wire to stretch in the front-rear direction;

the fixing piece comprises adjusting rods (102) which are connected to two ends of the cross beam (101) in a sliding mode, an electric push rod IV is arranged between the cross beam (101) and the adjusting rods (102), sleeves (103) are connected to the two adjusting rods (102) in a rotating mode, and locking screws are connected to the sleeves (103) in a threaded mode;

the fixing piece further comprises a gear (104) and a rack (105), the gear (104) is connected with the sleeve (103) through an upper key, the gear (104) is in meshed transmission connection with the rack (105), the rack (105) is connected to the adjusting rod (102) in a sliding mode, an electric push rod V is arranged between the rack (105) and the adjusting rod (102), the electric push rod V is started to drive the rack (105) to reciprocate, the rack (105) drives the gear (104) to rotate, the sleeve (103) is driven to rotate, copper wires in the sleeve (103) are driven to rotate, and therefore the circumferential surface of the whole copper wires is processed;

grinding the clean copper wire after removing the oxide layer into powder to obtain conductive filler, and uniformly mixing the conductive filler, an adhesive, a solvent and an additive to obtain the conductive ink.

2. The system for processing conductive ink of claim 1, wherein: annular grooves (303) are formed in the two ends of the circular ring I (301) respectively, and convex rings (403) capable of being embedded into the annular grooves (303) are arranged in the two ends of the circular ring II (401) respectively.

3. The system for processing conductive ink of claim 1, wherein: the H-shaped frame (202) is fixedly connected to the sliding sleeve seat (201), and the sliding sleeve seat (201) is connected to the cross beam (101) in a sliding mode.

4. A method of processing conductive ink using a conductive ink processing system of claim 3, wherein: the method comprises the following steps:

a: inserting waste copper wires into the corresponding two sleeves (103) for fixing, wherein the copper wires are positioned between the circular ring I (301) and the circular ring II (401);

b: the ring I (301) and the ring II (401) are controlled to rotate in opposite directions, and an oxide layer on the surface of the copper wire is polished;

c: the rotating circular ring I (301) and the circular ring II (401) are controlled to be close to each other to roll the copper wire, and the copper wire is extruded to deform;

d: grinding the clean copper wire after removing the oxide layer into powder to obtain conductive filler, and uniformly mixing the conductive filler, an adhesive, a solvent and an additive to obtain the conductive ink.