CN219861660U - Supercritical intelligent heating temperature gradient composite electrodeposition device - Google Patents
Supercritical intelligent heating temperature gradient composite electrodeposition device Download PDFInfo
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- CN219861660U CN219861660U CN202320896195.7U CN202320896195U CN219861660U CN 219861660 U CN219861660 U CN 219861660U CN 202320896195 U CN202320896195 U CN 202320896195U CN 219861660 U CN219861660 U CN 219861660U
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- 238000004070 electrodeposition Methods 0.000 title claims abstract description 39
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- 239000003292 glue Substances 0.000 claims abstract description 24
- 238000000034 method Methods 0.000 claims abstract description 14
- 239000000463 material Substances 0.000 claims abstract description 7
- 238000005507 spraying Methods 0.000 claims abstract description 6
- 239000007788 liquid Substances 0.000 claims description 72
- 238000009713 electroplating Methods 0.000 claims description 23
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- 230000008569 process Effects 0.000 claims description 9
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Abstract
The utility model discloses a supercritical intelligent heating temperature gradient composite electrodeposition device, which has a simple structure and a convenient operation method, in a supercritical state, the temperature rise time can be intelligently adjusted through an intelligent heating plate according to the thickness of a plating layer, the material property and the difference of electrodeposition technology, and the device is suitable for surface plating layers with different heating requirements; the automatic plating part mounting system automatically mounts the plating part on the fixture electrode and sprays insulating glue, so that automation of fixture plating part mounting and insulating glue spraying is realized, labor is saved, and experimental efficiency is improved.
Description
Technical Field
The utility model belongs to the technical field of electrochemical machining, and particularly relates to a supercritical intelligent heating temperature gradient composite electrodeposition device.
Background
One or more insoluble solid particles are uniformly mixed into the metal electrodeposited layer by an electrochemical electrodeposition method to form a special electrodeposited layer, and the electrodeposition method is called composite electrodeposition. The deposited metal alloy is referred to as a matrix of composite electrodeposited layers, and the solid particles are referred to as dispersants. Compared with the common electrodeposition, the composite electrodeposition requires high deposition speed and high current efficiency, and the solid particles should have a sufficiently good suspension state in the electrodeposition liquid, so that the uniform co-deposition of the solid particles is facilitated. Supercritical fluid technology is applied to the field of electrodeposition, and a supercritical fluid-based electrodeposition technology has been developed.
The high-temperature high-pressure supercritical reaction device is a device for carrying out chemical reaction on a reaction sample in a supercritical state or in a supercritical medium, and the medium used by the device is generally environment-friendly supercritical medium, such as supercritical water and supercritical CO 2 The existing supercritical reaction device on the market has the defects of single function, complex operation, low efficiency, pinholes, tumor accumulation and the like on the surface of the obtained coating, and the quality is not superior.
Disclosure of Invention
In order to solve the existing technical problems, the utility model provides the supercritical intelligent heating temperature gradient composite electrodeposition device, and under the supercritical state, intelligent heating temperature gradient conditions are built for composite electrodeposition, thereby being beneficial to improving the surface quality of a coating and obtaining a more excellent coating.
The utility model adopts the following technical scheme to realize the technical purposes:
the utility model provides a compound electro-deposition device of supercritical intelligent heating temperature gradient, includes reation kettle subassembly, intelligent heating temperature gradient system, stirring system, supercritical control system and plating solution circulation system, wherein:
the reaction kettle assembly comprises a kettle body, a kettle cover and a clamp, wherein the kettle body comprises a kettle inner cavity and a kettle outer cavity, the kettle cover is used for sealing the kettle inner cavity and the kettle outer cavity, and the clamp is arranged below the kettle cover and is positioned in the kettle inner cavity; the bottom of the kettle body is provided with a stirring system;
the intelligent heating temperature gradient system comprises an intelligent heating plate, an intelligent heating resistor and a heat sensor, wherein the intelligent heating plate is arranged outside the kettle body, the heat sensor is arranged in the outer cavity of the kettle, and the intelligent heating resistor is arranged on the back of the cathode of the clamp and is positioned in the inner cavity of the kettle;
the supercritical control system comprises an air inlet system and an air outlet system, wherein the air inlet system and the air outlet system are arranged on two sides of the kettle body and are communicated with the inner cavity of the kettle so as to detect and control the inlet and outlet of supercritical gas;
the electroplating solution circulation system comprises a liquid inlet system and a liquid discharge system, wherein the liquid inlet system is arranged on the kettle cover for allowing plating solution or cleaning solution to enter the inner cavity of the kettle, and the liquid discharge system is arranged at the bottom of the kettle body for discharging waste liquid in the inner cavity of the kettle.
Preferably, the reactor assembly further comprises a pulsed power supply connected to the top of the tank cap to deliver current to the clamp for electroplating.
Preferably, the stirring system comprises a magnetic force generator and a magnetic rotor, wherein the magnetic force generator is arranged outside the kettle body and below the bottom, and the magnetic rotor is arranged at the center of the bottom of the inner cavity of the kettle.
Preferably, the intelligent heating plate is fixed outside the kettle body through an intelligent heating plate fixing shell.
Preferably, the air inlet system comprises an air inlet pipeline, and a first electric valve, a first pressure gauge, a temperature detector and a second electric valve are sequentially arranged on the air inlet pipeline; the exhaust system comprises an exhaust pipeline, and a second pressure gauge, a third electric valve and an exhaust box are sequentially arranged on the exhaust pipeline.
After the first electric valve is opened, supercritical gas enters the pipeline through the first electric valve, when the first pressure gauge and the temperature detector detect that the pressure and the temperature of the supercritical gas meet the supercritical required pressure and temperature, the second electric valve is opened, the supercritical gas enters the inner cavity of the kettle, the third electric valve is opened after the experiment is finished, and waste gas enters the waste gas tank through the second pressure gauge.
Preferably, the liquid inlet system comprises a liquid inlet pipeline, and a first liquid inlet, a fourth electric valve and a first liquid outlet are sequentially arranged on the liquid inlet pipeline; the liquid discharging system comprises a liquid discharging pipeline, and a second liquid inlet, a fifth electric valve and a second liquid outlet are sequentially arranged on the liquid discharging pipeline.
Plating solution or cleaning solution enters the inner cavity of the kettle through the first liquid inlet and the first liquid outlet under the control of the fourth electric valve, and waste liquid is discharged into the waste liquid pool through the second liquid inlet and the second liquid outlet under the control of the fifth electric valve.
Preferably, the intelligent heating plate is used for heating the kettle body, and then heating the plating solution in the kettle body to enable the plating solution to reach a set temperature; the heat sensor is used for sensing the temperature of the kettle body, so that heating is stopped when the plating solution in the inner cavity of the kettle reaches the set temperature, and the plating solution in the inner cavity of the kettle is controlled at the set temperature; the intelligent heating resistor is used for heating the cathode of the clamp at regular time, heating is stopped after the regular time is finished, and the cathode is heated for a plurality of times during electroplating, so that the temperature of the cathode of the clamp is higher than the temperature of the inner cavity of the kettle.
Preferably, the intelligent heating plate intelligently adjusts the heating time according to the thickness of the plating layer, the material property and the electrodeposition process.
Preferably, the device further comprises a plating automatic mounting system, wherein the plating automatic mounting system further comprises a clamp fixing system and a plating clamping system, and the clamp fixing system comprises a rotatable clamp fixing table for fixing and rotating a clamp and a rotatable electrode fixing table for rotating an electrode; the plating part clamping system is provided with a clamping clamp for clamping a plating part on the electrode of the clamp and a lifting insulating glue dispenser for spraying insulating glue on the non-electroplating non-insulating part of the electrode.
Preferably, the lifting insulating glue dispenser comprises an insulating glue dispenser and a lifting table, and the insulating glue dispenser is lifted through the lifting table.
Compared with the prior art, the utility model has the following advantages:
the supercritical intelligent heating temperature gradient composite electrodeposition device disclosed by the utility model has the advantages that the structure is simple, the operation method is convenient, in a supercritical state, the temperature rise time can be intelligently adjusted according to the thickness of a plating layer, the material property and the difference of electrodeposition processes through the intelligent heating plate, the device is suitable for surface plating layers with different heating requirements, in addition, the intelligent heating resistor heats the cathode for a plurality of times in the electroplating process so that the temperature of the cathode of a clamp is higher than the temperature of plating solution, and a staged temperature gradient is formed between the cathode and the inner cavity of a kettle, thereby being beneficial to improving the activity of cathode ions, improving the electrodeposition rate, reducing defects such as pinholes and tumor accumulation, ensuring that the surface of the plating layer is compact and flat, and improving the surface quality and mechanical property of the plating layer; the automatic plating part mounting system automatically mounts the plating part on the fixture electrode and sprays insulating glue, so that automation of fixture plating part mounting and insulating glue spraying is realized, labor is saved, and experimental efficiency is improved.
Drawings
FIG. 1 is a schematic diagram of a supercritical intelligent heating temperature gradient composite electrodeposition device according to the present utility model.
FIG. 2 is a schematic view of the automatic plating part mounting system of the present utility model.
In the figure:
11. the kettle comprises a kettle body, 111, a kettle inner cavity, 112, a kettle outer cavity, 12, a kettle cover, 13, a clamp, 14 and a pulse power supply;
2. the intelligent heating temperature gradient system comprises an intelligent heating temperature gradient system, an intelligent heating plate fixing shell, an intelligent heating plate, a heat sensor and an intelligent heating resistor, wherein the intelligent heating temperature gradient system comprises an intelligent heating temperature gradient system, an intelligent heating plate fixing shell, an intelligent heating plate, a heat sensor and an intelligent heating resistor;
3. a stirring system 31, a magnetic rotor 32 and a magnetic force generator;
41. the air inlet system 410, an air inlet pipeline 411, a first electric valve 412, a first pressure gauge 413, a temperature detector 414 and a second electric valve; 42. an exhaust system 420, an exhaust pipeline 421, a second pressure gauge 422, a third electric valve 423 and an exhaust gas box;
51. the liquid inlet system 510, the liquid inlet pipeline 511, the first liquid inlet 512, the fourth electric valve 513 and the first liquid outlet; 52. the liquid discharge system 520, a liquid discharge pipeline 521, a second liquid inlet 522, a fifth electric valve 523, a second liquid outlet 524 and a waste liquid pool;
61. the fixture fixing system 611, the rotatable electrode fixing table 612, the rotatable fixture fixing table 62, the plating part clamping system 621, the clamping pliers 622, the insulating glue dispenser 623 and the lifting table.
Detailed Description
The technical solutions in the embodiments of the present utility model will be further described below with reference to the accompanying drawings in the embodiments of the present utility model, but not limited thereto. It will be apparent that the described embodiments are only some, but not all, embodiments of the utility model. All modifications and equivalent substitutions to the technical proposal of the utility model are included in the protection scope of the utility model without departing from the spirit and scope of the technical proposal of the utility model.
Examples
In order to improve the surface quality of a plating layer of a plating piece prepared by supercritical electrodeposition equipment under the existing condition and improve the mechanical property of the plating layer, the embodiment provides a supercritical intelligent heating temperature gradient composite electrodeposition device which comprises a reaction kettle component, an intelligent heating temperature gradient system 2, a stirring system 3, a supercritical control system and a plating solution circulating system, wherein,
the reaction kettle assembly comprises a kettle body 11, a kettle cover 12, a clamp 13 and a pulse power supply 14, wherein the kettle body 11 comprises an annular kettle inner cavity 111 and an annular kettle outer cavity 112, the kettle cover 12 is used for sealing the kettle inner cavity 111 and the kettle outer cavity 112, the clamp 13 is arranged below the kettle cover 12 and is positioned in the kettle inner cavity 111, the clamp 13 is connected to the bottom of the kettle cover 12, the pulse power supply 14 is connected with the top of the kettle cover 12, and pulse current is transmitted to the clamp 13 for electroplating.
The intelligent heating temperature gradient system 2 comprises an intelligent heating plate fixing shell 21, an intelligent heating plate 22, a heat sensor 23 and an intelligent heating resistor 24, wherein the intelligent heating plate 22 is arranged outside the kettle body 11 and is fixed by the intelligent heating plate fixing shell 21 (also arranged outside the kettle body 11), the intelligent heating plate 22 is used for heating the kettle body 11 and then heating the plating solution in the kettle body 11 to a certain temperature, specifically, the heating time of the intelligent heating plate 22 can be intelligently adjusted according to the thickness of a plating layer, the material property and the electrodeposition process, the heating time is controllable longer when the plating layer is thicker, and the heating time is controllable shorter when the plating layer is thinner. When the thermal conductivity of the plating material is better, the heating power is lower to adjust, the heating process is longer to control, and when the thermal conductivity of the plating material is worse, the heating power is higher to adjust, and the heating process is shortened. When the electrodeposition process is that the high current is firstly deposited, then the medium current and the low current are changed, the heating power is correspondingly adjusted, when the high current is deposited, the electrodeposition rate is higher, the heating power is required to be increased, the heating process is accelerated, and when the medium current and the low current are deposited, the electrodeposition rate is slower, the heating power can be reduced, and the heating process is prolonged.
The thermal sensor 23 is arranged in the outer cavity 112 of the kettle and is used for sensing the temperature of the kettle body 11, so that heating is stopped when the plating solution in the inner cavity 111 of the kettle reaches a certain temperature, the plating solution in the inner cavity 111 of the kettle is controlled at a certain temperature, the intelligent heating resistor 24 is arranged on the back surface of the negative electrode of the clamp 13 and is positioned in the inner cavity 111 of the kettle and is used for heating the cathode at regular time, after the timing is finished, heating is stopped, the cathode is heated for a plurality of times during electroplating, and the temperature of the cathode of the clamp is higher than the temperature of the inner cavity of the kettle.
For example, the temperature of the intelligent heating plate 22 is controlled to be more than 30 ℃ such as 35 ℃, and the temperature of the plating solution in the inner cavity of the kettle reaches 35 ℃ under the action of the heat sensor 23, so that the plating solution meets the temperature required by the supercritical condition; during electroplating, the intelligent heating resistor 24 heats the cathode for multiple times at regular time, so that the temperature of the cathode is higher than the temperature of the inner cavity 111 of the kettle at regular time, and a temperature gradient is formed between the cathode of the clamp and the plating solution in the inner cavity of the kettle during electroplating, so that the ions of a cathode plating piece are more active, the electrodeposition rate is improved, the plating layer is smooth and compact, defects such as pinholes and accumulated tumors are reduced, and the surface quality of the plating layer is improved.
The stirring system 3 comprises a magnetic rotor 31 and a magnetic force generator 32 which are matched with each other, the magnetic rotor 31 is arranged at the bottom center of the inner cavity 111 of the kettle, the magnetic force generator 32 is arranged outside the kettle body 11, and after the magnetic force generator 32 works, the magnetic rotor 31 rotates along with the magnetic force generator to stir the plating solution.
The supercritical control system comprises an air inlet system 41 and an air outlet system 42, wherein the air inlet system 41 and the air outlet system 42 are arranged on two sides of the kettle body 11 and are communicated with the kettle inner cavity 111 to detect and control the inlet and outlet of supercritical gas; the air intake system 41 comprises an air intake pipeline 410, a first electric valve 411, a first pressure gauge 412, a temperature detector 413 and a second electric valve 414 are sequentially arranged on the air intake pipeline 410, the air exhaust system 42 comprises an air exhaust pipeline 420, a second pressure gauge 421, a third electric valve 422 and an exhaust gas box 423 are sequentially arranged on the air exhaust pipeline 420, after the first electric valve 411 is opened, carbon dioxide gas enters the pipeline through the first electric valve 411, the first pressure gauge 412 and the temperature detector 413 sequentially detect the pressure and the temperature of the carbon dioxide gas, if the carbon dioxide gas accords with the supercritical required pressure and the supercritical required temperature, the second electric valve 414 is opened, the carbon dioxide gas enters the inner cavity 111 of the kettle, after the experiment is finished, the third electric valve 422 is opened, and the waste gas enters the exhaust gas box 423 through the second pressure gauge 421.
The electroplating solution circulation system comprises a liquid inlet system 51 and a liquid discharge system 52, wherein the liquid inlet system 51 is arranged on the kettle cover 12 so that the electroplating solution or cleaning solution can enter the kettle inner cavity 111, and the liquid discharge system 52 is arranged at the bottom of the kettle body 11 so that the waste liquid in the kettle inner cavity 111 can be discharged. The liquid inlet system 51 comprises a liquid inlet pipeline 510, a first liquid inlet 511, a fourth electric valve 512 and a first liquid outlet 513 are sequentially arranged on the liquid inlet pipeline 510, and plating liquid or cleaning liquid enters the inner cavity 111 of the kettle through the first liquid inlet 511 and the first liquid outlet 513 under the control of the fourth electric valve 512; the tapping system 52 comprises a tapping pipeline 520, and a second liquid inlet 521, a fifth electric valve 522 and a second liquid outlet 523 are sequentially arranged on the tapping pipeline 520, and waste liquid is discharged into a waste liquid pool 524 through the second liquid inlet 521 and the second liquid outlet 523 under the control of the fifth electric valve 522.
The automatic plating part mounting system comprises a clamp fixing system 61 and a plating part clamping system 62, wherein the clamp fixing system 61 comprises a rotatable electrode fixing table 611 and a rotatable clamp fixing table 612, the rotatable electrode fixing table 611 is used for rotating an electrode, insulating glue is sprayed on the front surface and the back surface of the electrode, the rotatable clamp fixing table 612 is used for fixing a clamp, and clamping of a plating part and insulating glue spraying are facilitated by switching positions of the clamp; the plating piece clamping system 62 further comprises a clamping clamp 621, an insulating glue dispenser 622 and a lifting table 623, wherein the clamping clamp 621 is used for clamping a plating piece on an electrode, the insulating glue dispenser 622 is used for spraying insulating glue on a non-electroplating non-insulating part of the clamp electrode, and the lifting table 623 is used for lifting the insulating glue dispenser 622, so that the insulating glue can be uniformly sprayed on the surface of the electrode.
The working principle of the utility model is as follows:
the clamp 13 installs the metal parts required by the anode and the cathode on the automatic plating part installation system and sprays insulating glue, and then the clamp 13 is taken down and the kettle cover 12 seals the kettle body 11; adding the prepared plating solution containing metal ions into the surfactant, and adding the plating solution into the inner cavity 111 of the kettle through a first liquid inlet 511;
carbon dioxide gas enters an air inlet pipeline 410 through a first electric valve 411, is detected by a first pressure gauge 412 and a temperature detector 413, and enters the inner cavity 111 of the kettle after meeting the supercritical required pressure and temperature by opening a second electric valve 414;
starting the magnetic force generator 32 to enable the magnetic rotor 31 of the inner cavity 111 of the kettle to rotate, stirring the plating solution, enabling the plating solution to be in uniform contact with the plating piece clamped on the clamp, improving the electroplating efficiency, and enabling the plating layer to be compact and flat;
opening an intelligent heating plate 22, a heat sensor 23 and an intelligent heating resistor 24 to heat the plating solution in the inner cavity 111 of the kettle to a certain temperature to reach a supercritical condition, and enabling the intelligent heating resistor 24 to heat the cathode of the clamp at regular time during electroplating to enable the temperature of the cathode of the clamp to be higher than the temperature of the inner cavity of the kettle, so as to construct a temperature gradient system;
after primary electroplating is completed, the pulse power supply 14 is turned off, the magnetic force generator 32 is turned off, the intelligent heating plate 22, the heat sensor 23 and the intelligent heating resistor 24 are turned off, carbon dioxide gas in the inner cavity 111 of the kettle is discharged into the waste gas box 423, waste plating solution in the inner cavity 111 of the kettle is discharged through the liquid discharge system 52, clean water is injected through the liquid inlet system 51, the magnetic force generator 32 is turned on, the magnetic rotor 31 rotates, the inner cavity 111 of the kettle is cleaned, then clean water is discharged through the liquid discharge system 52, and then new plating solution is injected into the inner cavity 111 of the kettle through the liquid inlet system 51 for secondary electroplating.
And after the secondary electroplating is finished, if the electroplating is needed to be continued, the process is repeated, after the electroplating is finished, the waste plating solution is discharged, the inner cavity 111 of the kettle is cleaned by clean water, then the kettle cover 12 and the clamp 13 are detached, and the cathode plating piece is detached, so that the experiment is completed.
The pulse power supply 14, the intelligent heating plate 22, the intelligent heating resistor 24, the heat sensor 23, the magnetic force generator 32, the temperature detector 413, the first electric valve 411, the second electric valve 414, the third electric valve 422, the fourth electric valve 512, the fifth electric valve 522, the rotatable fixture fixing table 612, the rotatable electrode fixing table 611, the clamping pincers 621, the insulating glue dispenser 622 and the lifting table 623 are all electrically connected. Through the electricity connection, can convenient and fast's control equipment start-up and close, control gas circuit and liquid way break-make improve operating efficiency, in the experimentation, can save experimenter's operation procedure, simplify experimental process, improve work efficiency.
The foregoing embodiments of the present utility model are only examples, and therefore, the scope of the utility model is not limited by the above embodiments, and all equivalent structures or equivalent processes using the descriptions and the drawings of the present utility model or direct or indirect application in other related technical fields are included in the scope of the utility model.
Claims (10)
1. The utility model provides a compound electro-deposition device of supercritical intelligent heating temperature gradient which characterized in that, includes reation kettle subassembly, intelligent heating temperature gradient system, mixing system, supercritical control system and plating solution circulation system, wherein:
the reaction kettle assembly comprises a kettle body, a kettle cover and a clamp, wherein the kettle body comprises a kettle inner cavity and a kettle outer cavity, the kettle cover is used for sealing the kettle inner cavity and the kettle outer cavity, and the clamp is arranged below the kettle cover and is positioned in the kettle inner cavity; the bottom of the kettle body is provided with a stirring system;
the intelligent heating temperature gradient system comprises an intelligent heating plate, an intelligent heating resistor and a heat sensor, wherein the intelligent heating plate is arranged outside the kettle body, the heat sensor is arranged in the outer cavity of the kettle, and the intelligent heating resistor is arranged on the back of the cathode of the clamp and is positioned in the inner cavity of the kettle;
the supercritical control system comprises an air inlet system and an air outlet system, wherein the air inlet system and the air outlet system are arranged on two sides of the kettle body and are communicated with the inner cavity of the kettle so as to detect and control the inlet and outlet of supercritical gas;
the electroplating solution circulation system comprises a liquid inlet system and a liquid discharge system, wherein the liquid inlet system is arranged on the kettle cover for allowing plating solution or cleaning solution to enter the inner cavity of the kettle, and the liquid discharge system is arranged at the bottom of the kettle body for discharging waste liquid in the inner cavity of the kettle.
2. The supercritical intelligent heating temperature gradient composite electrodeposition device according to claim 1 wherein the reactor assembly further comprises a pulsed power source connected to the top of the kettle cover to deliver current to the fixture for electroplating.
3. The supercritical intelligent heating temperature gradient composite electrodeposition device according to claim 1 wherein the stirring system comprises a magnetic force generator and a magnetic rotor, wherein the magnetic force generator is disposed outside the kettle body below the bottom, and the magnetic rotor is disposed at the bottom center of the kettle inner cavity.
4. The supercritical intelligent heating temperature gradient composite electrodeposition device according to claim 1 wherein the intelligent heating plate is fixed outside the kettle body by an intelligent heating plate fixing housing.
5. The supercritical intelligent heating temperature gradient composite electrodeposition device according to claim 1, wherein the air inlet system comprises an air inlet pipeline, and a first electric valve, a first pressure gauge, a temperature detector and a second electric valve are sequentially arranged on the air inlet pipeline; the exhaust system comprises an exhaust pipeline, and a second pressure gauge, a third electric valve and an exhaust box are sequentially arranged on the exhaust pipeline.
6. The supercritical intelligent heating temperature gradient composite electrodeposition device according to claim 1, wherein the liquid inlet system comprises a liquid inlet pipeline, and a first liquid inlet, a fourth electric valve and a first liquid outlet are sequentially arranged on the liquid inlet pipeline; the liquid discharging system comprises a liquid discharging pipeline, and a second liquid inlet, a fifth electric valve and a second liquid outlet are sequentially arranged on the liquid discharging pipeline.
7. The supercritical intelligent heating temperature gradient composite electrodeposition device according to claim 1, wherein the intelligent heating plate is used for heating the kettle body, and then heating the plating solution in the kettle body to reach a set temperature; the heat sensor is used for sensing the temperature of the kettle body, so that heating is stopped when the plating solution in the inner cavity of the kettle reaches the set temperature, and the plating solution in the inner cavity of the kettle is controlled at the set temperature; the intelligent heating resistor is used for heating the cathode of the clamp at regular time, heating is stopped after the regular time is finished, and the cathode is heated for a plurality of times during electroplating, so that the temperature of the cathode of the clamp is higher than the temperature of the inner cavity of the kettle, and a temperature gradient is formed.
8. The supercritical intelligent heating temperature gradient composite electrodeposition device according to claim 7 wherein the intelligent heating plate intelligently adjusts the temperature rise time according to the thickness of the coating, the material properties and the electrodeposition process.
9. The supercritical intelligent heating temperature gradient composite electrodeposition apparatus according to any one of claims 1 to 8 further comprising a plating automatic mounting system, the plating automatic mounting system further comprising a jig fixing system and a plating clamping system, the jig fixing system comprising a rotatable jig fixing stage for fixing and rotating a jig and a rotatable electrode fixing stage for rotating an electrode; the plating part clamping system is provided with a clamping clamp for clamping a plating part on the electrode of the clamp and a lifting insulating glue dispenser for spraying insulating glue on the non-electroplating non-insulating part of the electrode.
10. The supercritical intelligent heating temperature gradient composite electrodeposition device according to claim 9, wherein the liftable insulating glue dispenser comprises an insulating glue dispenser and a lifting table, and the insulating glue dispenser is lifted by the lifting table.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202320896195.7U CN219861660U (en) | 2023-04-20 | 2023-04-20 | Supercritical intelligent heating temperature gradient composite electrodeposition device |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202320896195.7U CN219861660U (en) | 2023-04-20 | 2023-04-20 | Supercritical intelligent heating temperature gradient composite electrodeposition device |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN219861660U true CN219861660U (en) | 2023-10-20 |
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Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202320896195.7U Active CN219861660U (en) | 2023-04-20 | 2023-04-20 | Supercritical intelligent heating temperature gradient composite electrodeposition device |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN219861660U (en) |
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2023
- 2023-04-20 CN CN202320896195.7U patent/CN219861660U/en active Active
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