RU2006121780A - METHOD FOR CLEANING AND POLISHING THE PRODUCT SURFACE (OPTIONS) - Google Patents

Claims (4)

1. The method of cleaning and polishing the surface of the product, including the ignition of a multi-channel discharge between the workpiece and the electrolyte, by supplying the product with a positive potential, characterized in that the workpiece is placed directly above the surface of the electrolyte at a distance of not more than 1 mm, the discharge is ignited and the product is gently immersed in the flowing electrolytic cathode at a breakdown distance from the metal plate located at the bottom of the electrolytic cell, set the voltage between th anode, which is the workpiece, and electrolyte - cathode ranging 10≤U≤650 B and discharge current set 0,025≤I≤200 A at electrolyte temperature of 40 _<e T <60 ° C, which is provided by creating a circulation of the electrolyte and additional cooling of the workpiece, the process is carried out for at least one minute with at least 10% saturation of the electrolyte and composition with atomic ionization potential U _φ <6 eV, where U is the discharge voltage between the electrodes, I is the discharge current, T _e is the temperature electrolyte. 2. The method of cleaning and polishing the surface of the product, including the ignition of a multi-channel discharge between the workpiece and the electrolyte, characterized in that the workpiece is placed directly above the surface of the electrolyte at a distance of not more than 1 mm, a negative potential is applied to the workpiece and a positive potential to the electrolyte ignite the discharge and the product is smoothly immersed in the flowing electrolytic anode at a non-breakdown distance from the metal plate located at the bottom of the electrolytic Coy cell voltage is set between the solid cathode, which is the workpiece, and the electrolyte - the anode in a range 10≤U≤650 B and discharge current set 0,025≤I≤200 A at electrolyte temperature of 40 _<e T <60 ° C, which provide by creating an electrolyte circulation and additional cooling of the workpiece, the process is carried out for at least one minute with at least 10% saturation of the electrolyte and composition with atomic ionization potential U _φ <6 eV, where U is the discharge voltage between the electrodes; I is the discharge current; T _e - the temperature of the electrolyte. 3. The method of cleaning and polishing the surface of the product, including ignition of the discharge between the workpiece and the electrolyte, characterized in that the electrolyte is a jet anode consisting of a laminar flow, and a negative potential is applied to the product, which is placed under the stream, and the voltage between the electrodes is established 200≤U≤650 V and the discharge current is set to 0.015≤I≤10000 mA, with an electrolyte flow rate of 2≤G≤16 · 10 ⁶ m ³ / s, with a diameter of the laminar section of the electrolyte anode stream d _c ≥0.5 mm, with a length jets l = 8 ÷ 100 mm, osu process estvlyayut for a time not less than one minute at least 10% saturated with the electrolyte composition and ionization potential of atoms U _φ <6 eV where U - the voltage between the electrodes, I - discharge current; G is the electrolyte consumption. 4. The method of cleaning and polishing the surface of the product, including ignition of the discharge between the workpiece and the electrolyte, characterized in that the electrolyte is a jet anode consisting of a laminar stream and crushed unsteady streams, and a negative potential is applied to the product that is placed under the stream , the voltage between the electrodes is 200≤U≤650 V and the discharge current is set to 0.015≤I≤10000 mA, with an electrolyte flow rate of 2≤G≤16 · 10 ⁶ m ³ / s, with a diameter of the laminar section of the electrolyte anode jet d _c ≥0, 5 m, with the overall length of the jet of electrolyte 8 ÷ l = 120 mm, the process is carried out for at least one minute at least 10% saturated with the electrolyte composition and ionization potential of atoms U _φ <6 eV where U - the voltage between the electrodes; I is the discharge current; G is the electrolyte consumption.