Electropolishing process means for an inner surface of a long tube

Information

  • Patent Application
  • 20030098245
  • Publication Number
    20030098245
  • Date Filed
    February 19, 2002
    22 years ago
  • Date Published
    May 29, 2003
    21 years ago
Abstract
The present invention is an electropolishing process means for an inner surface of a long tube, especially applied to a long tube of greater than two meters and a diameter range between 0.3 to 5 cm. Wherein, the present invention comprises at least one tube, one complex electrode; an inner surface of the tube is for electropolishing process, and it is an anode as well; the electrode is a cathode and placed on a center of a partition; an end of electrode connects to a cable, the cable is driven by an axial mechanism to be moved toward the axial mechanism itself; inside tube are full of electrolyte, which is an electrifying medium to connect both anode and cathode, further, electrolyte cooperates with electrode to move for electropolishing process the inner surface of tube.
Description


1. FIELD OF THE INVENTION

[0001] The present invention is an electropolishing process means for an inner surface of a long tube, especially applied to a long tube of greater than two meters and an inside diameter range between 0.3 to 5 cm.



2. BACKGROUND OF THE INVENTION

[0002] A process of electropolishing is to connect a workpiece to an anode and a metal to a cathode, aforesaid whole structure of workpiece connecting to anode and metal connecting to cathode is put into electrolyte for electrifying direct current, thus defects on workpiece surface are removed and the surface is then shining and smooth. Features of electropolishing are that improving surface cleanness, roughness, passivation, etc. For different fields of semiconductor, chemical industry, biochemical engineering, food industry, needed tubes of aforesaid fields are to deliver fluids of those fields, and inner surfaces of tubes are treated by polish or electrolysis to approach high cleanness and anti-corrosion. Especially, products of IC/LCD/III-V require high standards of cleanness and anti-corrosion, thus, applying the present invention to said products is a challenge.


[0003] In prior arts of U.S. Pat. Nos. 4,826,582 and 4,849,084, which were figuring out part of the technologies of electropolishing a 10-meter heat exchange tube, and an electrode device for positioning workpiece and sealing electrolyte is a must. The prior arts adopt a 3-layer structure of delivering electrolyte of high pressure air, but unfortunately said structure is very complicate and only suitable for the larger diameter workpieces, not for the tube of inside diameter under 3 cm.


[0004] In prior art of U.S. Pat. No. 5,958,195, which was the technology of electropolishing an inner surface of a long and bended tube. However, to electropolish a bended tube, electrode must move alone bended curve for not happening short circuit. The most important parts are a flexible electrode and an insulation device. The insulation-device is to avoid short circuit and non-concentricity, but this kind of devices block electrolyte flowing and makes un-average electric field, etc.


[0005] In prior arts of U.S. Pat. Nos. 4,601,802 and 4,705,611, which offer a fixture applied an inside tube, and the fixture stabilizes a plurality of axially rotating tubes simultaneously. An end connector can circulate tube and exhaust gas from an upper end, and electrolyte can be recycled after overflowing. An electrode length is equal to the tube length, therefore a huge space and a super power supplier are needed to fit such conditions.


[0006] Based on the aforesaid issues, the present inventor of the patent has being studied and referred to practical experiences and theory for designing and effectively improving the prior arts.



SUMMARY OF THE INVENTION

[0007] The first object is to offer an electropolishing process means for an inner surface of a long tube, which improves an electrode design and applies theories of macro and micro polishing to an electrode means for improving a manufacturing rate in both smoothing and passivation effect on the surface of workpiece.


[0008] The second object is to offer an electropolishing process means for an inner surface of a long tube, which can treat an inner surface of a tube greater than 2 meters and an inside diameter range of 0.3 to 5 cm; a structure of the means is simple to save an equipment cost.


[0009] The third object is to offer an electropolishing process means for an inner surface of a long tube, which avoids short circuit and non-concentricity problems. An electrode of the present invention is installed through a center of a partition, so the electrode has a certain distance with the inner surface in tube because the partition supports electrode. Therefore, the short circuit and non-concentricity are solved; further, the average electric field is kept all the time because of the partition is round.


[0010] The fourth object is to offer an electropolishing process means for an inner surface of a long tube, which electrode can be designed as multi-section, to do so figures out that needing a huge space to store such similar equipment; further, the electrode can be added to different sections depending on needs to improve electrolyzing and polishing result.


[0011] The appended drawings will provide further illustration of the present invention, together with description; serve to explain the principles of the invention.







BRIEF DESCRIPTION OF THE DRAWINGS

[0012]
FIG. 1 is a scheme of a practical application of the present invention.


[0013]
FIG. 2 is a first preferred embodiment of the present invention.


[0014]
FIG. 3 is a preferred embodiment of an electrode of the present invention.


[0015]
FIG. 4 is a second preferred embodiment of the present invention.


[0016]
FIG. 5 is a third preferred embodiment of the present invention.


[0017]
FIG. 6 is a sectional view of a partition of the present invention.







DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0018] For different fields of semiconductor, pharmaceutical industry chemical industry, biochemical engineering, food industry, inner surfaces of needed tubes and fitting of aforesaid fields are treated by electropolishing process for improving surface cleanness, roughness and passivation results. The present invention comprises an electrolyte delivering system, which makes electrolyte averagely pass through an inner surface of a long tube; a cable, which guides direct current to a working area of an inner surface of tube, and electrolyte is an electrifying media to make a complete electric path. An end of the cable can be added an insulated electrode means, which slowly moves along with an imagine central axis of tube for a cathode electrode not contacting onto an anode electrode, thus short circuit problem is then evaded. The electrode means is complex for approaching a huge and fine polishing result, such as a Cu—W bar.


[0019] Referring to FIG. 1, which is a scheme of a practical application of the present invention. Electrolyte is stored in a tank 10, and a heater 11 is inside the tank 10 for keeping electrolyte temperature. Electrolyte passes through a switch 12 and a pipe 23 to a tube 16, wherein the switch 12 is made of Teflon or other heat-resistant and acid-proof materials. The tube 16 is placed on an inclined platform 17, and thus a higher end of tube 16 connects to the pipe 23 for electrolyte passing from higher end to a lower end. Inclined angles of the inclined platform 17 can be adjusted to control electrolyte flowing speeds. Tube 16 includes at least one electrode (not shown in FIG. 1), which is hung up by a cable 20, and another end of the cable 20 is rolled up by an axial mechanism 22; The axial mechanism 22 rolls up cable 20 to move the electrode upward when electropolishing process reaction being proceeded inside tube 16. The present invention adopts that electron exchanging from an anode half reaction and a cathode half reaction to generate an electropolishing process result. Tube 16 is an anode, thus an inner surface of tube 16 is anode, and anode looses electrons; the electrode is cathode, and cathode receives electrons; FIG. 1 does not show the electrode, so only cable 20 is shown up to represent above connection relationship. Tube 16 is about 2 meters long or more than that, so electrolyte temperature is lower when electrolyte approaching to a lowest end of tube 16, thus plural halogen bulbs 15 are placed around tube 16 for heating. Electrolyte is recycled after passing through tube 16 to a recycling tank 13, then it is delivered back to tank 10 by a pump 14 with heat-resistant and acid-proof. As aforesaid, which is a complete procedure for electropolishing process. Following is a detail description.


[0020] Referring to FIG. 2, which is a first preferred embodiment of the present invention. In the embodiment, a partition 18, an electrode 21 and a propeller 19 are in a tube 16; the electrode 21 is hung up by a cable 20 and driven by an axial mechanism 22 to move toward the axial mechanism 22. Electrolyte is full of inside tube 16, and a diameter of the partition 18 is slightly smaller than an inner diameter of tube 16 (a diameter range of electropolishing process of the present invention is between 0.3 to 5 cm), therefore partition 18 floats in tube 16 and is almost perpendicular to the inner surface of tube 16, so partition 18 cannot touch onto the inner surface of tube 16. Finally, cable 20 electrifies direct current to electrode 21 and through a medium of electrolyte to the inner surface; the electropolishing process reaction is then started. Electrode 21 is placed on a center of partition 18, and it is double electrodes, which is complex for approaching a huge and fine polishing result; besides, electrode 21 can be made by different materials, such as copper, wolfram, stainless steel, etc. On the other hand, electrode 21 can be single as well (not shown in figure), and the single electrode is positioned between partition 18 and the propeller 19. The reaction is preceded only between them, so electropolishing process goes slowly. Propeller 19 is to quickly exhaust air bulbs generated by reaction, because air bulbs affect polished surface. When electrolyte flowing from an end close to axial mechanism 22 to another end of tube 16, propeller 19 is also driven by axial mechanism 22 to opposite direction, and it rotates and vortex is generated by aforesaid relative motion as well. Air bulbs in between partition 18 and the propeller 19 and another side of partition 18 are exhausted fast. Referring to FIG. 5, which is a third preferred embodiment of the present invention. Propeller 19 can be instead of a screw slideway 24, and air bulbs go through the screw slideway 24 to outside; obviously, screw slideway 24 functions as propeller 19. As shown in FIG. 2, plural slots 25 are designed on an outer edge of partition 18, those slots 25 make electrolyte flow close to inner surface more fluently and a boundary layer is then broken to generate an average anode membrane, such flow effectively brings air bulbs out. Referring to FIG. 6, which is a sectional view of a partition of the present invention. For fluently introducing electrolyte, partition 18 has many holes 26 as meshes; further, partition 18 is made of Teflon of insulated material for saving total energy and enhancing electropolishing process result. Another function of partition 18 is to avoid contacting of negative electrode and positive inner surface, hence short circuit and non-concentricity are solved; further, the average electric field is kept all the time because partition 18 is round. Partition 18 is variable for different tube diameters.


[0021] Referring to FIG. 3, which is a preferred embodiment of an electrode of the present invention. The electrode can be made of plural materials for different levels of polishing. A complex electrode consists of a first electrode 211 and a second electrode 212 for two-stage electropolishing process reaction, and it is to promote result shown as in FIG. 1.


[0022] Referring to FIG. 4, which is a second preferred embodiment of the present invention. An electrode 21 of the preferred embodiment includes a third electrode 213, a fourth electrode 214, a fifth electrode 215 and a sixth electrode 216; this is for multi-stage reaction, and it seems each kind of electropolishing process reaction can be approached from the embodiment.


[0023] While the present invention has been shown and described with reference to preferred embodiments thereof, and in terms of the illustrative drawings, it should be not considered as limited thereby. Thus, the present invention is infinitely used. However, various possible modification, omission, and alterations could be conceived of by one skilled in the art to the form and the content of any particular embodiment, without departing from the scope and the sprit of the present invention.


[0024] The invention is disclosed and is intended to be limited only the scope of the appended claims and its equivalent area.


Claims
  • 1. An electropolishing process means for an inner surface of a long tube comprising: at least one tube having an inner surface for being polished, said tube being inclined for electrolyte flowing from a higher place to a lower place when electrolytic and polish being proceeding, tube being made of material of electric conductivity; at least one partition being placed inside tube, said partition dividing at least two spaces in tube for electropolishing process, a diameter of partition being slightly smaller than an inner diameter of tube, partition floating in tube and being almost perpendicular to the inner surface of tube, so partition not touching onto the inner surface of tube; and at least one electrode being placed on a center of partition, the electrode being in a space divided by partition, an end of electrode connecting to a cable, the cable being connected by an axial mechanism, said axial mechanism driving cable to move electrode toward axial mechanism itself.
  • 2. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein the means electrolyzes and polishes a range of 0.3 to 5 cm of the tube inner diameter.
  • 3. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein the means electrolyzes and polishes tube greater than two meters.
  • 4. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein the inner surface is anode of the reaction.
  • 5. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein the partition is made of one of the following materials: Teflon, insulated material, etc.
  • 6. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein plural slots are designed on an outer edge of partition, the slots make electrolyte flow close to inner surface more fluently, a boundary layer is then broken to generate an average anode membrane.
  • 7. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein plural slots are designed on an outer edge of partition, the slots make electrolyte flow close to inner surface more fluently, such flow effectively brings out air bulbs generated by reaction.
  • 8. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein the partition has many holes as meshes for fluently introducing electrolyte.
  • 9. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein the partition is variable for different tube diameters.
  • 10. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein the partition can be a plurality depending on each need.
  • 11. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein the electrode is cathode.
  • 12. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein different materials depending on needs can organize the electrode.
  • 13. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein an end of the electrode connecting to cable has a screw structure for fast remove air bulbs.
  • 14. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein the screw structure is one of the following: propeller, screw slideway.
  • 15. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein the electrode can be organized by a plurality of following materials: copper, wolfram, stainless steel, etc.
  • 16. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein the tube is placed on an inclined platform.
  • 17. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein a higher end of the tube connects to a pipe, and the pipe connects to a tank.
  • 18. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein a recycling tank is placed under a lower end of the tube, electrolyte in the recycling tank is delivered back to tank by a pump.
  • 19. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein plural light bulbs are placed around tube for heating.
  • 20. The electropolishing process means for an inner surface of a long tube cited in claim 1, wherein the electrode is driven by axial mechanism to move a direction opposite to a direction of electrolyte flow.
Priority Claims (1)
Number Date Country Kind
90220569 Nov 2001 TW