CN202415726U - Metal electrodeposition device - Google Patents
Metal electrodeposition device Download PDFInfo
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- CN202415726U CN202415726U CN2011205498231U CN201120549823U CN202415726U CN 202415726 U CN202415726 U CN 202415726U CN 2011205498231 U CN2011205498231 U CN 2011205498231U CN 201120549823 U CN201120549823 U CN 201120549823U CN 202415726 U CN202415726 U CN 202415726U
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Abstract
The utility model discloses a metal electrodeposition device. The metal electrodeposition device comprises an electrodeposition tank and a power supply, wherein the outer side of the electrodeposition tank is provided with an electroacoustic transducer system which applies ultrasonic waves in a direction parallel or perpendicular to an electric field into an electrolyte in the electrodeposition process; the outer side of the electrodeposition tank is also provided with an N magnetic pole and an S magnetic pole which are used for applying a magnetic field parallel or perpendicular to the electric field in the electrolyte into the electrolyte in the electrodeposition process, the N magnetic pole and the S magnetic pole are oppositely distributed on two sides of the electrodeposition tank, and the intensity B of the magnetic field which is applied into the electrolyte by the N magnetic pole and the S magnetic pole is 0.5 to 1.0 T; and a stirrer which is used for stirring the electrolyte in the electrodeposition process and a heating system which is used for keeping the temperature of the electrolyte in the electrodeposition tank stable are also arranged in the electrodeposition tank. In the process of electrodepositing a metal material on a cathode, the direction and power of the ultrasonic waves and the direction and intensity of the magnetic field are selected for synergistic coupling and jointly act on the electrolyte so as to increase the speed and consistency of the electrodeposition.
Description
Technical field
The utility model belongs to the electro-chemical machining technical field, is specifically related to a kind of metal electrodeposition device.
Background technology
The metal electrodeposition technology is a kind of working method of metallic cation clad deposit to the negative electrode of under the extra electric field effect, utilizing in the ionogen.Its principle is in electrolyte solution, to constitute the loop by anode and negative electrode; Under electric field action; Make metal on the anode lose electronics and constantly incorporate electrolyte solution, and metals ion obtains electronics with the continuous process separated out of deposition of atoms metal form on negative electrode simultaneously with the ionic form.The metal electrodeposition technology is to increase material processing technology, mainly comprises galvanoplastics and electroplating technology etc.
Galvanoplastics is to utilize metals ion to obtain a kind of accurate manufacturing technology of metallic element at negative electrode core principles of electro-deposition.The electroforming ultimate principle is that the specified shape of processing is as required produced grand master pattern as negative electrode, as anode, together puts into the metal salt solution identical with anode material with electroforming material; The logical power supply of going up; Under electric field action, master surface deposits the metal electric cast layer gradually, from solution, takes out after reaching required thickness; Electroformed layer is separated with grand master pattern, just obtain and the corresponding metal duplicate of grand master pattern shape.The characteristics of electroforming are that the part that is shaped can very accurately duplicate core shape and fine structure thereof, have very high form accuracy and dimensional precision.
Electroplating technology is a kind of surface property that can change material, improves material appearance, makes material obtain a kind of working method of corrosion-resistant, wear-resistant, high temperature resistance and other properties.Its principle is needing the surface-treated part as negative electrode, as anode, together put into the metal salt solution identical with anode material with plated material, under electric field action, forming the settled layer of metal or alloy on the surface of negative electrode part after the energising.Electroplating technology requires coating should have even, smooth, densification and the good characteristics of bonding force.In recent years, electroplating technology has been widely applied in the every field of the industrial production and the product for civilian use, electroplates not only to make product surface exquisite appearance, hand feel and drape, and has more increased abrasion resistance properties and the corrosion resistance etc. of product surface.
Traditional metal electrodeposition technology also exists some key issues to improve, as the deposition layer surface pin hole and dross often appear, deposit thickness is inhomogeneous, electrodeposition rate is slow, material property difference etc.The existence of these problems can cause the degradation, galvanic deposit production efficiency of galvanic deposit processing and surface treatment part to reduce, even produces compelled the termination and scrap etc. with part, is seriously restricting the technological development of metal electrodeposition.At present, people have attempted many kinds of innovative approachs and method, are included in and are added with organic additive in the electrolytic solution, use reverse impulse electric current etc.These methods have been improved galvanic deposit quality of work piece surface and material property to a certain extent, have improved the thickness evenness of deposition layer.But the few and detection difficult of organic additive usage quantity often is mixed in constantly consumption of quilt in the deposition layer in electrodeposition process, not only make electrolytic solution difficult in maintenance, and influence the purity and the performance of galvanic deposit material.In addition, organic additive can work the mischief to producers, can cause environmental pollution again.And the reverse impulse electric current can reduce current efficiency, influences electrodeposition rate.Therefore, be necessary to explore new metal electrodeposition method and technology, with the key issue in the practical application of effective solution metal electrodeposition technology.
The utility model content
The purpose of the utility model is to provide a kind of metal electrodeposition device, to solve the technical problem that settled layer hardness is low, compactness is poor, electrodeposition rate is low that occurs in the metal electrodeposition technology of the prior art.
For realizing above-mentioned purpose; The metal electrodeposition device that the utility model provided adopts following technical scheme: a kind of metal electrodeposition device; Comprise and be used for holding the galvanic deposition cell of electrolytic solution and being used at electrodeposition process and the anode of electrolytic solution and the power supply of the corresponding electrical connection of negative electrode; The described galvanic deposition cell outside is provided with in electrodeposition process and applies parallel or perpendicular to hyperacoustic electroacoustic transducer system of direction of an electric field to electrolytic solution; This electroacoustic transducer system is electrically connected with ultrasonic generator, and the ultrasonic frequency that electroacoustic transducer system is applied on the electrolytic solution is 45kHz, and ultrasonic power is 120~300W; The galvanic deposition cell outside also be provided be used for electrodeposition process to electrolytic solution apply parallel or perpendicular to electrolytic solution in the magnetic field N utmost point magnetic pole and the S utmost point magnetic pole of electric field; The corresponding both sides that are distributed in galvanic deposition cell of said N utmost point magnetic pole and S utmost point magnetic pole, the magneticstrength B that is applied in the electrolytic solution by N utmost point magnetic pole and S utmost point magnetic pole is 0.5~1.0T; In galvanic deposition cell, also be provided with the whisking appliance and the stable heating system of electrolyte temperature maintenance that is used to make galvanic deposition cell that in electrodeposition process, are used for stirring electrolytic solution.
Described N utmost point magnetic pole and S utmost point magnetic pole are around the rotating galvanic deposition cell outside that is transferred on of galvanic deposition cell central axis.
Described galvanic deposition cell week is supported with the fitter's bench that rotates around the galvanic deposition cell central axis through thrust block laterally; Corresponding respectively the placement on the revolution fitter's bench of described N utmost point magnetic pole and S utmost point magnetic pole is positioned at galvanic deposition cell week two carrier positions laterally, and two carriers are with respect to galvanic deposit central axis symmetric arrangement.
Described electroacoustic transducer system comprises bottom land electroacoustics transducer that is arranged on the galvanic deposition cell bottom and the groove side electroacoustics transducer that is positioned at the circumferential side of galvanic deposition cell; When said groove side electroacoustics transducer installation direction uses and the direction of an electric field in the galvanic deposition cell in the same way, bottom land electroacoustics transducer and groove side electroacoustics transducer be connected be used for controlling both working ordeies with obtain electrodeposition process to electrolytic solution apply perpendicular or parallel in electrolytic solution hyperacoustic ultrasonic wave controller of electric field.
Heating system in the described galvanic deposition cell comprises well heater, detects the thermopair of electrolyte temperature and is used for the temperature control unit according to the detected temperature control heater of the thermopair working hour.
The beneficial effect of the utility model is: in the metal electrodeposition method that the utility model provided in electrodeposition process; Apply parallel or perpendicular to the UW of electric field to electrolytic solution; And apply parallel or perpendicular to the magnetic field of electric field to electrolytic solution and negative electrode, anode, like this when UW and magnetic field act on the electrolytic solution in the zone simultaneously, because hyperacoustic ultrasonic cavitation, mechanical effect and heat effect (sound wave in communication process its portion of energy by medium absorption becoming heat energy); Be coupled to dispersive ability, covering power and the hydromagnetics effect of electrolytic solution are collaborative with magnetic field; Can increase to electrolytic solution to flow disturbance and thermogenic action, make that the metals ion group in the electrolytic solution is constantly broken, and the ratio of redox reaction activated molecule sharply increased; Speed of response is accelerated, thereby improves sedimentation velocity.Simultaneously; The long-range navigation magnetic force in hyperacoustic mechanical effect and magnetic field can promote the desorption of hydrogen on negative electrode to separate out; Reduce the current potential that hydrogen is separated out; The metallic cation refined crystalline strengthening of filling the air distribution, high density dislocation are strengthened and filled the air effect such as reinforcement to strengthen, can make deposition layer compact structure, smooth, strengthen the bonding force and the wear resistance of deposition layer.In addition; Because the hydromagnetics effect (MHD) in magnetic field, UW effect and electrolytic solution is carried out mechanical stirring and temperature control all can promote near the ion transport the electrode; Reduce the concentration difference polarization, make the metallic cation particulate evenly, stable suspersion in electroplate liquid, and then make the metal deposition laminar surface more smooth; Crystal grain is tiny; Improve the compactness and the bonding force of deposition layer, can effectively eliminate defectives such as deposition layer pin hole and dross, improve the quality of galvanic deposit processing parts and the quality that piece surface is handled.
The metal electrodeposition device that the utility model provided is provided with whisking appliance in galvanic deposition cell; The galvanic deposition cell arranged outside to electrolytic solution apply parallel or perpendicular to electrolytic solution in hyperacoustic electroacoustic transducer system of electric field; And the galvanic deposition cell outside also be provided with to electrolytic solution apply parallel or perpendicular to electrolytic solution in the N utmost point magnetic pole and the S utmost point magnetic pole in magnetic field of electric field, the corresponding both sides that are distributed in galvanic deposition cell of N utmost point magnetic pole and S utmost point magnetic pole.In electrodeposition process; Anode that at first will corresponding connection with the positive and negative electrode of power supply is vertical with negative electrode to be placed in the electrolytic solution of galvanic deposition cell; Form electric field between anode and the negative electrode; By whisking appliance the electrolytic solution in the galvanic deposition cell is carried out mechanical stirring, apply parallel to electrolytic solution or perpendicular to the UW of electric field, and apply parallel or perpendicular to the magnetic field of electric field to electrolytic solution and negative electrode and anode by the N utmost point magnetic pole of the both sides that are distributed in galvanic deposition cell and S utmost point magnetic pole by the electroacoustic transduction apparatus.In electrodeposition process; Strengthen cavitation effect, the disturbance effect of electrolytic solution through the synergy in UW and magnetic field; Improve the speed of galvanic deposit, improve crystal growth, obtain the deposition layer of grain refining; Reduce hydrogen deposition potential on negative electrode, reduce the pin hole and the dross defective of deposition layer.After deposition layer reaches specific thickness, cut off the electricity supply, stop galvanic deposit, will take out as the core of negative electrode, behind the cleaning-drying, isolate the electroforming part, perhaps take off the surface-treated electroplating parts from negative electrode, the whole galvanic deposit course of processing is accomplished.
Description of drawings
Fig. 1 is the structural representation of a kind of embodiment of metal electrodeposition device of providing of the utility model.
Embodiment
A kind of embodiment of the metal electrodeposition method that the utility model provided; Add man-hour at metal electrodeposition; Be placed in the electrolytic solution negative electrode is vertical with anode, then power cathode linked to each other with negative electrode, positive source is linked to each other with anode; In electrodeposition process; In electrolytic solution, form electric field by anode and negative electrode, apply parallel or perpendicular to the UW of direction of an electric field, and electrolytic solution, negative electrode, anode are applied parallel or act synergistically perpendicular to the magnetic field and the UW of direction of an electric field electrolytic solution; Simultaneously; Electrolytic solution is carried out mechanical stirring; And make the temperature of electrolytic solution keep stable through heating system; In negative electrode powers on the deposit metallic material process, select the direction of direction and the magneticstrength and the electric field in hyperacoustic direction, frequency and power and magnetic field to carry out the coupling of following several kinds of schemes;
Wherein, scheme one, UW direction are perpendicular to direction of an electric field, and field direction is perpendicular to direction of an electric field, and ultrasonic frequency is 45kHz, and ultrasonic power is 120~300W, and magneticstrength B is 0.5~1.0T;
Scheme two, the UW direction is perpendicular to direction of an electric field, and field direction is parallel to direction of an electric field, and ultrasonic frequency is 45kHz, and ultrasonic power is 120~300W, magneticstrength B is 0.5~1.0T;
Scheme three, the UW direction is parallel to direction of an electric field, and field direction is parallel to direction of an electric field, and ultrasonic frequency is 45kHz, and ultrasonic power is 120~300W, magneticstrength B is 0.5~1.0T;
Scheme four, the UW direction is parallel to direction of an electric field, and field direction is perpendicular to direction of an electric field, and ultrasonic frequency is 45kHz, and ultrasonic power is 120~300W, magneticstrength B is 0.5~1.0T.
In the electrodeposition process of aforesaid method; Apply parallel or perpendicular to the UW of direction of an electric field to electrolytic solution; Exist between UW direction and the direction of an electric field vertically and concern with parallel two kinds of positions; Apply parallel to electrolytic solution and negative electrode, anode simultaneously or, have parallel and vertical two kinds of positions relation between field direction and the direction of an electric field equally perpendicular to the magnetic of electric field.Four kinds of matching schemes are arranged to adapt to different actual conditions after the permutation and combination, the correlation parameter of adjusting UW and magnetic field simultaneously is to satisfy the metal electrodeposition processing to the differing materials part.
Adopt above-mentioned metal electrodeposition technology working method, can improve electrodeposition efficiency, and prepare compactness height, thickness of coating is even and hardness is high electroforming part or plated item.
With electronickelling on stainless steel plate is example explanation present method effect.In the test, be stainless steel substrates (trade mark 2Cr13Mn9Ni4) at electroplating cathode, anode is a sheet nickel, and nickel plate purity is 99.9%, and cathode and anode is parallel and vertically be positioned in the galvanic deposition cell, and the ratio of its area is 2: 3, and interpole gap is 150mm.Power supply adopts the TPR3010H constant current regulated power supply, is equipped with 78HW-1 thermostatically heating magnetic stirring apparatus and carries out magnetic agitation.Electrolytic solution consists of: NiSO46H2O is 300g/L, and NiCl2 is 10g/L, and H3BO3 is 40g/L, and the pH value is 4.0.Current density is 4A/dm2 during galvanic deposit, and ultrasonic frequency is that 45kHz and power and direction are adjustable, and electrolytic solution is applied parallel or vertical magnetic field, and magneticstrength is adjustable.Electrolyte temperature is controlled at 45~50 ℃, and electroplating time is 1 hour.Measure thickness of coating behind the sample production and on HV S-1000 type digital display microhardness tester, measure the microhardness of coating material.Its result is following:
Be example explanation present method effect with electro-coppering on stainless steel plate again.In the test, electroplating cathode is stainless steel substrates (trade mark 2Cr13Mn9Ni4), and anode is a copper coin, and purity is 99.9%, and cathode and anode is parallel and vertically be positioned in the galvanic deposition cell, and the ratio of its area is 2: 3, and interpole gap is 150mm.Power supply adopts the TPR3010H constant current regulated power supply, is equipped with 78HW-1 thermostatically heating magnetic stirring apparatus and carries out magnetic agitation.The technical recipe that electrolytic solution is formed: CuSO45H2O is 250g/L, and H2SO4 is 50g/L, and the pH value is 3.2.Current density is 4A/dm2 during galvanic deposit, and ultrasonic frequency is that 45kHz and power and direction are adjustable, and electrolytic solution is applied parallel or vertical magnetic field, and magneticstrength is adjustable.Electrolyte temperature is controlled at 50~55 ℃, and electroplating time is 1 hour.Measure thickness of coating behind the sample production and on HV S-1000 type digital display microhardness tester, measure the microhardness of coating material.Its result is following:
Above-mentioned two routine experimental results can be found out the positive effect of this method and apparatus.After galvanic deposition cell is applied magnetic field and ultrasonic field, electroplate than routine, can see that electrodeposition rate is obviously very fast, coating hardness is also higher.
As shown in Figure 1; A kind of embodiment that is used to implement the metal electrodeposition device of above-mentioned metal electrodeposition method, the metal electrodeposition device among this embodiment comprises galvanic deposition cell support 22, on the galvanic deposition cell support, is installed with galvanic deposition cell 3; In galvanic deposition cell 3, add electrolytic solution 4; The negative electricity of negative electrode 8 with power supply 7 is connected, and anode 5 is connected with the positive pole of power supply 7, also is immersed in the electrolytic solution completely negative electrode and parallel being placed in the galvanic deposition cell of anode then; In electrolytic solution, form electric field, be provided with the whisking appliance 17 that in electrodeposition process, is used to stir electrolytic solution in the bottom of galvanic deposition cell 3 by anode and negative electrode.Temperature for control electrolytic solution; In galvanic deposition cell 3, also be provided with and be used in the heating system of electrodeposition process to electrolytic solution heating, heating system comprises well heater 20, detects the thermopair 19 of electrolyte temperature and is used for the temperature control unit 6 according to the detected temperature control heater of the thermopair working hour.Galvanic deposition cell 3 arranged outside have in electrodeposition process to electrolytic solution apply parallel or perpendicular to electrolytic solution in hyperacoustic electroacoustic transducer system of direction of an electric field; Electroacoustic transducer system comprises bottom land electroacoustics transducer 18 that is arranged on the galvanic deposition cell bottom and the groove side electroacoustics transducer 9 that is positioned at the circumferential side of galvanic deposition cell; Bottom land electroacoustics transducer and groove side electroacoustics transducer all are electrically connected with ultrasonic generator 15; Ultrasonic generator 15 is connected with computingmachine 11; Simultaneously bottom land electroacoustics transducer 18 and groove side electroacoustics transducer 9 all be electrically connected be used for controlling both working ordeies with obtain electrodeposition process to electrolytic solution apply parallel or perpendicular to electrolytic solution in hyperacoustic ultrasonic wave controller 16 of direction of an electric field; In electrodeposition process; According to the actual condition needs; By ultrasonic wave controller according to the steering order control flume that computingmachine sent at the bottom of electroacoustics transducer work obtaining perpendicular to the UW of direction of an electric field or the work of control flume side electroacoustics transducer obtaining being parallel to the UW of direction of an electric field, and adjust hyperacoustic power and the frequency that bottom land electroacoustics transducer or groove side electroacoustics transducer are applied through ultrasonic generator, preferred; The ultrasonic frequency that electroacoustic transducer system is applied on the electrolytic solution is 45kHz, and ultrasonic power is 120~300W.The outside of galvanic deposition cell 3 also be provided be used for electrodeposition process to electrolytic solution apply parallel or perpendicular to electrolytic solution in the N utmost point magnetic pole 2 and S utmost point magnetic pole 10 in magnetic field of direction of an electric field; The corresponding both sides that are distributed in galvanic deposition cell of N utmost point magnetic pole and S utmost point magnetic pole; N utmost point magnetic pole in the present embodiment and S utmost point magnetic pole are generated by two solenoids respectively; Solenoid is connected with field controller 12; Field controller 12 is connected with computingmachine 11; According to actual condition, adjust the magnitude of field intensity that N utmost point magnetic pole and S utmost point magnetic pole are applied by computingmachine output signal through field controller, the preferred magneticstrength B that is applied on the electrolytic solution by N utmost point magnetic pole and S utmost point magnetic pole is 0.5~1.0T.Be supported with the worktable 1 that rotates assembling around the galvanic deposition cell central axis in galvanic deposition cell 3 outsides through thrust block 21; On worktable 1, be positioned at the galvanic deposition cell both sides and have a carrier; Described N utmost point magnetic pole and S utmost point magnetic pole are corresponding respectively is installed in two carrier positions on the worktable; By computingmachine 11 controls, behind computingmachine output rotation command, worktable rotates around the galvanic deposition cell central axis worktable 1 through worktable unit 14; Drive N utmost point magnetic pole and S utmost point magnetic pole and rotate, thereby be implemented in the electrodeposition process perpendicular or parallel with the electric field in the electrolytic solution with S utmost point electrolytic solution that magnetic pole is applied to and negative electrode with the magnetic field on the anode by N utmost point magnetic pole.
Power supply in the foregoing description links to each other with computingmachine through the direct supply unit, like this can be according to the actual condition needs, by direct current or the pulse power in electrolytic solution negative electrode and anode supply and adjust the size of electric field current density.
UW control in the foregoing description has the system selector switch function and gets final product; Promptly can select the work of bottom land electroacoustics transducer so that the UW and the electric field in the electrolytic solution that are applied in the electrolytic solution are perpendicular, perhaps select the electroacoustics transducer work of groove side so that the UW and the electric field in the electrolytic solution that are applied in the electrolytic solution parallel.
N utmost point magnetic pole in the foregoing description and S utmost point magnetic pole are installed on the rotatable worktable; By worktable driving N utmost point magnetic pole and the rotation of S utmost point magnetic pole; In other embodiments; Also can N utmost point magnetic pole and S utmost point magnetic pole be suspended in the outside of galvanic deposition cell through the suspention disk, the suspention disk is provided with the circular orbit around the galvanic deposition cell layout, is slidedly assemblied in N utmost point magnetic pole and S utmost point magnetic pole in the circular orbit respectively; When the magnetic field that needs N utmost point magnetic pole and S utmost point magnetic pole to be applied, move N utmost point magnetic pole and S utmost point magnetic pole gets final product along circular orbit.
N utmost point magnetic pole in the foregoing description and S utmost point magnetic pole are installed on the rotatable worktable, and by worktable driving N utmost point magnetic pole and the rotation of S utmost point magnetic pole, thereby the field direction of realizing being applied on the electrolytic solution changes.N utmost point magnetic pole and S utmost point magnetic pole respectively are ends of a hot-wire coil; In other embodiments; Four coils can be set, will be wherein in two coil edges and the electrolytic solution parallel layout of direction of an electric field form first group of coil, the perpendicular direction of direction of an electric field in two other coil edge and the electrolytic solution is arranged forms second group of coil; Give first group of coil electricity; End towards galvanic deposition cell of two coils in first group of coil is respectively N utmost point magnetic pole and S utmost point magnetic pole, same gives second group of coil electricity, and the end towards galvanic deposition cell of two coils in second group of coil is respectively N utmost point magnetic pole and S utmost point magnetic pole; Like this through giving first group of coil electricity respectively or give second group of coil electricity, thereby obtain parallel or perpendicular to the magnetic field of direction of an electric field.
Use above-mentioned metal electrodeposition device to carry out galvanic deposit and add man-hour; Electrolytic solution 4 is placed galvanic deposition cell 3; The core that adopts conductive material (like stainless steel, duraluminum etc.) to process make negative electrode or with needs surface-treated electro-conductive material as negative electrode 8; Employing contains the anode 5 of the cationic material of galvanic deposit as galvanic deposit; Be placed in galvanic deposition cell 3 parallel with anode of negative electrode also is immersed in the electrolytic solution 4 fully, stirs electrolytic solution to quicken electrolyte flow by the whisking appliance in the electrolyzer 3 17.To electrolytic solution heating, and the working hour of the detection signal control heater of being exported according to thermopair 19 by temperature control unit is so that electrolytic solution keeps stable temperature by the well heater in the heating system 20.Apply UW through bottom land electroacoustics transducer 18 or groove side electroacoustics transducer 9 to electrolytic solution; Adjust hyperacoustic power and frequency through ultrasonic generator 15; And select to be applied to hyperacoustic direction and the power in the electrolytic solution through ultrasonic wave controller 16 according to galvanic deposit processing situation; Simultaneously; Apply magnetic field by N utmost point magnetic pole and S utmost point magnetic pole to electrolytic solution and anode and negative electrode; Magneticstrength is regulated and control through computingmachine 11 controlling magnetic field units 12 in the magnetic field here, and rotates around the galvanic deposition cell central axis through computingmachine 11 control worktable 1 and to realize the parallel of field direction and direction of an electric field or vertically process with the galvanic deposit that adapts to different situations, and the feasible magnetic field energy that is applied by N utmost point magnetic pole and S utmost point magnetic pole acts near a certain zone of the electrolytic solution galvanic deposit cathode surface along level or vertical direction.During galvanic deposit; With the energising of direct current or the pulse power, strengthen cavitation effect, the disturbance effect of electrolytic solution, the speed of raising galvanic deposit through the synergy in UW and magnetic field; Improve crystal growth; Obtain the deposition layer of grain refining, reduce hydrogen deposition potential on negative electrode, reduce the pin hole and the dross defective of deposition layer.After deposition layer reaches specific thickness, cut off the electricity supply, stop galvanic deposit, core is taken out, behind the cleaning-drying, isolate the electroforming part, perhaps take off the surface-treated electroplating parts from negative electrode.The whole galvanic deposit course of processing is accomplished.
Claims (5)
1. metal electrodeposition device; Comprise and be used for holding the galvanic deposition cell of electrolytic solution and being used at electrodeposition process and the anode of electrolytic solution and the power supply of the corresponding electrical connection of negative electrode; It is characterized in that: the described galvanic deposition cell outside is provided with in electrodeposition process and applies parallel or perpendicular to hyperacoustic electroacoustic transducer system of direction of an electric field to electrolytic solution; This electroacoustic transducer system is electrically connected with ultrasonic generator; The ultrasonic frequency that electroacoustic transducer system is applied on the electrolytic solution is 45kHz, and ultrasonic power is 120~300W; The galvanic deposition cell outside also be provided be used for electrodeposition process to electrolytic solution apply parallel or perpendicular to electrolytic solution in the magnetic field N utmost point magnetic pole and the S utmost point magnetic pole of electric field; The corresponding both sides that are distributed in galvanic deposition cell of said N utmost point magnetic pole and S utmost point magnetic pole, the magneticstrength B that is applied in the electrolytic solution by N utmost point magnetic pole and S utmost point magnetic pole is 0.5~1.0T; In galvanic deposition cell, also be provided with the whisking appliance and the stable heating system of electrolyte temperature maintenance that is used to make galvanic deposition cell that in electrodeposition process, are used for stirring electrolytic solution.
2. metal electrodeposition device according to claim 1 is characterized in that: described N utmost point magnetic pole and S utmost point magnetic pole are around the rotating galvanic deposition cell outside that is transferred on of galvanic deposition cell central axis.
3. metal electrodeposition device according to claim 2; It is characterized in that: described galvanic deposition cell week is supported with the fitter's bench that rotates around the galvanic deposition cell central axis through thrust block laterally; Corresponding respectively the placement on the revolution fitter's bench of described N utmost point magnetic pole and S utmost point magnetic pole is positioned at galvanic deposition cell week two carrier positions laterally, and two carriers are with respect to galvanic deposit central axis symmetric arrangement.
4. according to claim 1 or 2 or 3 described metal electrodeposition devices; It is characterized in that: described electroacoustic transducer system comprises bottom land electroacoustics transducer that is arranged on the galvanic deposition cell bottom and the groove side electroacoustics transducer that is positioned at the circumferential side of galvanic deposition cell; When said groove side electroacoustics transducer installation direction uses and the direction of an electric field in the galvanic deposition cell in the same way, bottom land electroacoustics transducer and groove side electroacoustics transducer be connected be used for controlling both working ordeies with obtain electrodeposition process to electrolytic solution apply perpendicular or parallel in electrolytic solution hyperacoustic ultrasonic wave controller of electric field.
5. metal electrodeposition device according to claim 4 is characterized in that: the heating system in the described galvanic deposition cell comprises well heater, detects the thermopair of electrolyte temperature and is used for the temperature control unit according to the detected temperature control heater of the thermopair working hour.
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CN2011205498231U CN202415726U (en) | 2011-12-24 | 2011-12-24 | Metal electrodeposition device |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102677137A (en) * | 2011-12-24 | 2012-09-19 | 河南科技大学 | Metal electrodeposition device |
CN104746117A (en) * | 2015-04-21 | 2015-07-01 | 江苏理工学院 | Cathode and anode synchronous frequency vibration type strong magnetic auxiliary electro-deposition processing device and method |
CN105463559A (en) * | 2015-12-16 | 2016-04-06 | 无锡福镁轻合金科技有限公司 | Plating tank with stirring function |
-
2011
- 2011-12-24 CN CN2011205498231U patent/CN202415726U/en not_active Withdrawn - After Issue
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102677137A (en) * | 2011-12-24 | 2012-09-19 | 河南科技大学 | Metal electrodeposition device |
CN102677137B (en) * | 2011-12-24 | 2015-03-18 | 河南科技大学 | Metal electrodeposition device |
CN104746117A (en) * | 2015-04-21 | 2015-07-01 | 江苏理工学院 | Cathode and anode synchronous frequency vibration type strong magnetic auxiliary electro-deposition processing device and method |
CN105463559A (en) * | 2015-12-16 | 2016-04-06 | 无锡福镁轻合金科技有限公司 | Plating tank with stirring function |
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