CN210560826U - Cluster cathode micro-arc oxidation film preparation device - Google Patents
Cluster cathode micro-arc oxidation film preparation device Download PDFInfo
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- CN210560826U CN210560826U CN201921126827.1U CN201921126827U CN210560826U CN 210560826 U CN210560826 U CN 210560826U CN 201921126827 U CN201921126827 U CN 201921126827U CN 210560826 U CN210560826 U CN 210560826U
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Abstract
The utility model discloses a cluster cathode micro-arc oxidation film preparation device, which comprises a distance adjusting device, an electrolytic bath, a cluster cathode, a power supply and a master control computer; the distance adjusting device comprises a workbench, a vertical arm, a transverse sliding block and a telescopic rod, wherein the telescopic rod is arranged on the transverse sliding block and can extend downwards and retract upwards under the action of a ball screw transmission mechanism driven by a servo motor; the electrolytic bath is made of an insulating material, is placed on the workbench and is used for containing electrolyte and a workpiece to be processed; the negative pole tied in a bundle is formed by a plurality of rod-like electrode combinations, and its upper end is fixed with the lower extreme installation of telescopic link, the beneficial effects of the utility model: the micro-arc oxidation device has the advantages of realizing the local or integral micro-arc oxidation of the surface of a large-size workpiece, reducing the limitation of the size of the workpiece on the output power of a power supply, improving the effective energy utilization rate of the power supply, controlling the arcing area, having strong controllability of the solution temperature and reducing the treatment cost of the micro-arc oxidation with large surface area.
Description
Technical Field
The utility model belongs to the technical field of micro arc oxidation film processing equipment, concretely relates to negative pole micro arc oxidation film preparation facilities tied in a bundle.
Background
At present, the micro-arc oxidation processing of the workpiece surface in China is mainly realized by directly immersing the workpiece in electrolyte as an anode, connecting an electrolytic bath with a power supply cathode as a cathode, and realizing the synchronous processing of the workpiece surface after electrifying without any relative motion between the cathode and the anode. The machining method has high dependence on power supply power, and due to the reasons of non-uniformity of conduction and heating, point discharge and area effects can occur on the surface of a workpiece, so that the requirement for determining machining process parameters is very strict. And the device is only suitable for workpieces with relatively simple surface shapes and relatively small sizes, and has no universality.
The scanning micro-arc oxidation technology is to reform the traditional micro-arc oxidation equipment, change the original stainless steel tank as a cathode into a stainless steel pipe with smaller cross section (related to power supply power), spray the working fluid from the steel pipe, form a small micro-arc discharge area by the anode and the cathode and the working fluid, and generate a micro-arc oxidation process in the area. The method is mainly used for treating the workpieces with larger surface areas, and the treatment effect on the workpieces with small areas is not ideal.
SUMMERY OF THE UTILITY MODEL
The utility model discloses the technical problem who solves: the traditional micro-arc oxidation technology brings larger area effect and point discharge phenomenon, and has higher requirement on power supply power; the single scanning type micro-arc oxidation treatment has low precision and low treatment efficiency on small-area workpieces.
The utility model provides a technical scheme that its technical problem adopted is: a cluster cathode micro-arc oxidation film preparation device comprises a distance adjusting device, an electrolytic bath, a cluster cathode, a power supply and a master control computer;
the distance adjusting device comprises a workbench, a vertical arm, a transverse sliding block and a telescopic rod, wherein the vertical arm is arranged on the workbench, the transverse sliding block is arranged on the vertical arm, the telescopic rod is arranged on the transverse sliding block, and the telescopic rod can extend downwards and can be recovered upwards under the action of a ball screw transmission mechanism driven by a servo motor;
the electrolytic tank is made of plastic materials, is placed on the workbench and is used for containing electrolyte and a workpiece to be processed;
the cluster cathode is formed by combining a plurality of rod-shaped electrodes, the upper end of the cluster cathode is fixedly installed with the lower end of the telescopic rod, and the lower end of the cluster cathode extends into the electrolytic bath;
the cathode of the power supply is connected with the cluster cathode, and the anode of the power supply is connected with the workpiece;
the master control computer is electrically connected with the power supply and the distance adjusting device.
Further, the vertical arm can linearly reciprocate on the workbench under the action of a ball screw transmission mechanism driven by a servo motor.
Further, the transverse moving slide block can reciprocate linearly left and right on the vertical arm under the action of a ball screw transmission mechanism driven by a servo motor.
On the basis of the scheme, the electrolytic cell further comprises a cooling tank, the cooling tank is placed on the workbench, the whole electrolytic cell is placed in the cooling tank filled with cooling water, a water inlet and a water outlet are formed in the cooling tank, and the height of the water inlet is lower than that of the water outlet.
Preferably, the power supply is a numerical control double-pulse power supply and is connected with a master control computer through an RS485 protocol.
Preferably, each electrode bundle of the bundled cathode is wrapped by rubber.
Preferably, the distance adjusting device is connected with a master control computer and can realize accurate positioning by adopting G code programming.
The utility model has the advantages that:
1. local or integral micro-arc oxidation of the surface of a large-size workpiece is realized, the limitation of the size of the workpiece on the output power of a power supply is reduced, and the effective energy utilization rate of the power supply is improved;
2. the arcing area is controllable, the solution temperature is highly controllable, and the treatment cost of large-surface-area micro-arc oxidation is reduced;
3. on the basis of determining the micro-arc oxidation power supply, the combination of the discharge area is favorably and quickly determined, so that the quick matching of the discharge area and the power supply is realized;
4. different bundling form combination experiments can be carried out on the same equipment, and the electrode distance is controllable.
Drawings
Fig. 1 is a schematic structural diagram of a distance adjustment device according to an embodiment of the present invention;
FIG. 2 is a diagram of the power supply electrode according to an embodiment of the present invention;
fig. 3 is a schematic view of a cluster cathode structure according to an embodiment of the present invention.
Detailed Description
The technical solution of the present invention will be further explained with reference to the drawings in the embodiments of the present invention.
As shown in figures 1 and 2, the device for preparing the micro-arc oxidation film of the cluster cathode comprises a distance adjusting device, a cooling tank 1, an electrolytic tank 2, the cluster cathode 5, a power supply 6 and a main control computer 7.
As shown in fig. 2, the distance adjusting device comprises a workbench 81, a vertical arm 82, a traverse slide block 83 and a telescopic rod 84, wherein the vertical arm 82 can linearly reciprocate on the workbench 81 under the action of a servo motor driven ball screw transmission mechanism; the transverse moving slide block 83 is arranged on the vertical arm 82 and can reciprocate linearly left and right on the vertical arm 82 under the action of a servo motor driving ball screw transmission mechanism; the telescopic rod 84 is arranged on the transverse moving slide block 83 and can extend downwards and retract upwards under the action of a ball screw transmission mechanism driven by a servo motor.
The cluster cathode 5 is formed by combining a plurality of cluster rod-shaped electrodes, and each cluster electrode is wrapped by rubber, so that the mutual influence between the clusters is effectively avoided, and the processing precision is improved. The cluster cathode 5 is connected with the negative electrode of the power supply 6 to be used as a cathode. The workpiece 3 is fixed at the bottom of the electrolytic bath 2 and is connected with the positive pole of the power supply 6 to be used as an anode.
The cluster cathode 5 is detachably connected with the lower end of the telescopic rod 84, so that the exchange among different clusters is facilitated. The distance adjusting device is connected with the main control computer 7, accurate positioning can be achieved by adopting G code programming, and accurate adjustment in X, Y, Z three directions can be achieved. The vertical up-and-down movement of the cluster cathode 5 is used for selecting different electrode distances according to different workpieces, the requirement of the size of the workpieces on the output power of the power supply is reduced, and the effective energy utilization rate of the power supply is improved. And the horizontal movement in two directions can perform scanning type processing on a large-size workpiece on one hand and process different positions of the workpiece on the other hand. The method can be used for integrally processing the large-size workpiece and also can be used for carrying out local micro-arc oxidation processing on the large workpiece.
The electrolytic tank 2 is made of plastic materials, is internally provided with electrolyte and is integrally placed in the cooling tank 1 filled with cooling water. The cooling tank 1 is provided with a water inlet and a water outlet, wherein the water inlet is designed to be lower than the water outlet, and cooling water circularly flows so as to realize the maximum cooling effect. The cooling bath 1 is placed on a table 81.
The power supply 6 is a numerical control double-pulse power supply and can adjust positive voltage, negative voltage, positive current, negative current, duty ratio, pulse frequency and the like required by reaction. The power supply 6 is connected with the master control computer 7 through an RS485 protocol, can dynamically monitor the electrical parameters of the reaction in real time, and can acquire data.
As shown in fig. 3, which is a cross-sectional view of the cluster cathode assembly, the cluster cathode 5 has various combinations. In the figure, the combination of the shapes of the lines is arranged in a row, the combination is in an isosceles triangle shape, the combination is in a square shape, and the combination is in a regular hexagon shape. By combining the shapes of the simple rod-shaped electrodes, the shapes of complex workpieces are processed in an adaptive manner, so that the effective energy utilization rate of a power supply is improved, and the controllability of the surface quality and the thickness of the film layer is realized.
Processing example: the experimental material adopts aviation aluminum, is a plate-shaped material, and is provided with a hole with the diameter of 6mm at the upper left corner for clamping the base of the electrolytic cell 2 and fixing the workpiece. The treatment process comprises the steps of sequentially polishing with 240 #, 400 # and 800 # sandpaper, placing the polished sandpaper into an acetone solution for ultrasonic cleaning twice for 10 min, and then blowing the cleaned sandpaper to dry and bagging the cleaned sandpaper for later use by using a common blower. Na2SiO3 is used as a main film forming agent of the electrolyte, and NaOH and C6H15NO3 (triethanolamine) are used as additives. On the basis of the existing experimental verification of optimal setting of electrical parameters, the electrical parameters are set to 20% of duty ratio with voltage of 500V and oxidation time of 900s and frequency of 400Hz, and the change of the electrode spacing is set to 2-40mm for experimental verification. This is achieved by a precise adjustment device, i.e. the vertical distance between the anode and the cathode and the relative displacement before the start of the reaction are adjustable, so that the film structure can be obtained at different reaction gaps. Counting the size and the number of arc spots, reading the electrical parameters by an RS485 protocol, observing the surface micro-topography of the ceramic film by using an TESCAN VEGA-XMU type scanning electron microscope, measuring the thickness of the film by using an eddy current thickness gauge, measuring 8 points, removing extreme values, and taking an average value.
The distance adjusting device is used for transforming the experiment platform on the basis of adopting a normally balanced electromechanical engraving machine and carrying out accurate positioning of movement by using a G code program, so that distance controllability operation between the cathode and the anode is realized, and multi-distance adjustment verification can be realized.
A preparation method of a cluster cathode micro-arc oxidation film is implemented according to the following steps:
step 1: the cluster cathode is connected with the negative electrode of a power supply, the power supply is a numerical control double-pulse power supply, the whole electrolytic tank is placed into a cooling tank, cooling water which circularly flows is arranged in the cooling tank, the electrolytic tank is made of an insulating material and is filled with electrolyte, and the electrolyte is filled with Na2SiO3As a main film-forming agent, the film-forming agent, NaOH、C6H15NO3as additive dissolved in solvent water; the cluster cathode consists of a plurality of rod-shaped electrodes, the upper end of the cluster cathode is arranged on the distance adjusting device, the lower end of the cluster cathode extends into electrolyte in the electrolytic cell, and the distance adjusting device drives the cluster cathode to move accurately in the x, y and z directions relative to the workpiece under the control of a main control computer;
step 2: sequentially polishing a workpiece with 240 #, 400 # and 800 # sandpaper, putting the workpiece into an acetone solution for ultrasonic cleaning twice for 10 min, and then blowing the workpiece to dry and bagging the workpiece for later use by using a common blower;
and step 3: fixedly placing the workpiece processed in the step 2 in an electrolytic bath, immersing the workpiece in electrolyte, connecting the workpiece with the positive electrode of a power supply, and setting the distance change between the cluster cathode and the workpiece to be 2 mm; setting the electrical parameters as voltage 500V, oxidation time 900s, frequency 400Hz, duty ratio 20%, current density 10A/dm2The oxidation time is 900S;
and 4, step 4: observing the surface micro-topography of the ceramic film layer by using an TESCAN VEGA-XMU type scanning electron microscope, measuring the thickness of the film layer by using an eddy current thickness gauge, measuring to obtain a plurality of points, removing extreme values, and taking an average value.
The preparation method of the bundled cathode micro-arc oxide film comprises the steps of 1-4, wherein the step of 1-4 is carried out for a plurality of times in a circulating mode, the distance between the bundled cathode and a workpiece in the step 3 is increased by 1mm each time, the relation between the distance between the bundled cathode and the workpiece and the sizes of an oxide film layer and an arc spot is researched, and a numerical relation table between the distance between the bundled cathode and the workpiece and the thickness of the oxide film layer is obtained.
The electrolyte is added with 1-5g/L of Na2SiO30.5-2g/L NaOH and 0.1-2g/L C as main film-forming agents6H15NO3As additive dissolved in solvent water;
the utility model has the advantages that the good surface processing quality is easy to obtain, the local or integral micro-arc oxidation can be efficiently carried out on the large-size workpiece in the practical aspect, the data is transmitted to the computer through the RS485 protocol, the analysis and the processing of the electrical parameters are convenient, and the optimal micro-arc oxidation scheme can be obtained by changing the distance between a plurality of cluster cathodes and the electrodes; trial and error processing can be performed in the same equipment.
It is to be understood that although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations may be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.
Claims (5)
1. A cluster cathode micro-arc oxidation film preparation device is characterized by comprising a distance adjusting device, an electrolytic bath (2), a cluster cathode (5), a power supply (6) and a master control computer (7);
the distance adjusting device comprises a workbench (81), a vertical arm (82), a transverse sliding block (83) and an expansion rod (84), wherein the vertical arm (82) is arranged on the workbench (81), the transverse sliding block (83) is arranged on the vertical arm (82), and the expansion rod (84) is arranged on the transverse sliding block (83) and can extend downwards and retract upwards under the action of a ball screw transmission mechanism driven by a servo motor;
the electrolytic tank (2) is made of plastic materials, is placed on the workbench (81) and is used for containing electrolyte and a workpiece (3) to be processed;
the cluster cathode (5) is formed by combining a plurality of rod-shaped electrodes, the upper end of the cluster cathode is fixedly installed with the lower end of the telescopic rod (84), the lower end of the cluster cathode extends into the electrolytic bath (2), and each electrode of the cluster cathode (5) is wrapped by rubber;
the cathode of the power supply (6) is connected with the cluster cathode (5), and the anode is connected with the workpiece (3);
the master control computer (7) is electrically connected with the power supply (6) and the distance adjusting device.
2. The cluster cathode micro-arc oxidation film preparation device according to claim 1, wherein the vertical arm (82) can linearly reciprocate on the worktable (81) under the action of a servo motor driven ball screw transmission mechanism.
3. The cluster cathode micro-arc oxidation film preparation device according to claim 2, wherein the traverse slide block (83) can reciprocate linearly left and right on the vertical arm (82) under the action of a servo motor driven ball screw transmission mechanism.
4. The cluster cathode micro-arc oxidation film preparation device according to claim 1, further comprising a cooling tank (1), wherein the cooling tank (1) is placed on the workbench (81), the electrolysis bath (2) is integrally placed in the cooling tank (1) filled with cooling water, the cooling tank (1) is provided with a water inlet and a water outlet, and the height of the water inlet is lower than that of the water outlet.
5. The cluster cathode micro-arc oxidation film preparation device according to claim 1, wherein the power supply (6) is a numerical control double-pulse power supply and is connected with a main control computer (7) through an RS485 protocol.
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| CN201921126827.1U CN210560826U (en) | 2019-07-18 | 2019-07-18 | Cluster cathode micro-arc oxidation film preparation device |
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| CN201921126827.1U CN210560826U (en) | 2019-07-18 | 2019-07-18 | Cluster cathode micro-arc oxidation film preparation device |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN110230082A (en) * | 2019-07-18 | 2019-09-13 | 烟台大学 | A kind of boundling cathode micro arc oxidation membrane preparation device and method |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN110230082A (en) * | 2019-07-18 | 2019-09-13 | 烟台大学 | A kind of boundling cathode micro arc oxidation membrane preparation device and method |
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Effective date of registration: 20240118 Address after: No. 104, Unit 2, Building 33, No. 188 Qinhuaihe Road, Economic and Technological Development Zone, Yantai City, Shandong Province, 264000 Patentee after: Wang Yong Address before: 264005, Qingquan Road, Laishan District, Shandong, Yantai, 30 Patentee before: Yantai University |
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Effective date of registration: 20240327 Address after: Room 302, Middle District, No. 3 Huanghe Road, Economic and Technological Development Zone, Yantai City, Shandong Province, 264000 Patentee after: Yantai Hongcheng Electrical Automation Co.,Ltd. Country or region after: China Address before: No. 104, Unit 2, Building 33, No. 188 Qinhuaihe Road, Economic and Technological Development Zone, Yantai City, Shandong Province, 264000 Patentee before: Wang Yong Country or region before: China |
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