KR20130102420A - Anodic oxidation system using parallel operation process - Google Patents

Abstract

PURPOSE: An anodic oxidizer using a parallel process is provided to implement multiple anode oxidation experiments at the same time with one laboratory device. CONSTITUTION: An anodic oxidizer using a parallel process comprises a water tub (100), a power pack (200), and a display unit. In n-tuple (n is more than 2) of water tubs, an electrolyte is charged in an inside, and an anode oxidation about each sample mounted on an inside is performed. The power pack supplies an electric power. The power pack is formed as a form having a rated current and a rated voltage of X [V] and P [A]. In the power pack, n-tuple of anode ports and one common ground port are formed. N-tuple of the anode ports is connected to n-tuple of anode terminals of the water tub individually. The one common ground port is branched to n-tuple in parallel, and connected to a cathode terminal of the water tub.

Description

Anodic oxidation system using parallel operation process

The present invention relates to an anodizing device using a parallel process, and more particularly, using a parallel process capable of simultaneously implementing a plurality of anodizing experiments with one experimental device by connecting the power sources in parallel using one power source. It relates to an anodizing device.

In general, anodization has been widely used to prevent corrosion or color the metal surface by forming an oxide film on the metal surface as one of the surface treatment techniques of the metal, but recently, such as nano dots, nanowires, nanotubes, nanorods, etc. It is widely used as a method of directly forming a nanostructure or manufacturing a mold for forming a nanostructure.

Such metals that can form nanostructures by anodization are known as Al, Ti, Zr, Hf, Ta, Nb, W, etc. Among them, aluminum anodization films are easy to manufacture and use other fluorine ions. Unlike metals, electrolyte handling is relatively safe, and nanoporosity and thickness control are easy, making it widely used in nanotechnology research.

Anodization of aluminum includes mild anodization with a low film growth rate of several micrometers per hour at relatively low voltages and hard anodization with a film growth rate of several tens of micrometers per hour at relatively high voltages. Known.

In order to anodize the metal as described above, an anodizing device is used. The anodizing device according to the prior art may be represented by three main components, as shown in FIG. 1.

The anodizing device includes a water tank 100 in which anodization is performed, a power unit 400 for supplying a predetermined amount of voltage and current to the water tank, and data connected to the power unit 400 in real time. It is composed of a display unit 300 that can be observed.

The tank 100 is filled with an electrolyte, and the positive electrode terminal is connected to the positive electrode of the power port of the power unit, and a sample for forming an oxide is installed. And the negative electrode terminal is connected to the negative electrode of the power port of the power unit is provided with a counter electrode such as platinum.

The power unit 400 is provided with a power port for supplying power to the water tank 100 to supply an appropriate amount of voltage and current for anodization. Internally, the main data extracted from the anodized specimen, which is a sample, for example, the data such as the current flowing through the sample specimen over time, is obtained in real time and automatically, stored in a computer, A control unit, which is a data acquisition system (also called "DAQ") composed of computer programs and algorithms such as LabVIEW for controlling, is formed, and the data acquisition system is linked with a display unit to monitor a computer. Through the experimenter is configured to observe the data in real time.

However, the above-described prior art uses the power pack rated power ([rated power] = [rated voltage] × [rated current] even though the power pack, which is essentially applied to the anodization experiment, has sufficient voltage and current capacity). Only one experiment using low power, which is less than enough) is performed. Therefore, in order to perform another experiment, the experiment may be completed after the previous experiment or another similar anodizing device. There are problems of inefficiency and inefficiency of research, such as purchasing and experimenting.

Accordingly, the present invention has been made to solve the above problems of the prior art, using a parallel process that can simultaneously implement a number of anodization experiments in one experimental apparatus by connecting the power in parallel using one power source. It is an object to provide an anodizing device.

The present invention for achieving the above object is filled with an electrolyte therein, n (n is 2 or more) of the water tank is anodized for each sample mounted therein; A power pack for supplying a predetermined amount of current and voltage to the n tanks; N anode ports formed in the power pack and individually connected to anode terminals respectively formed in the n tanks; One common ground port formed in the power pack and individually connected in parallel with negative terminals respectively formed in the n tanks; An anodizing device using a parallel process formed in the power pack and configured to include n on / off switches for controlling the power supply of the n anode ports is a technical subject.

The power pack is preferably formed with a control unit for controlling the experimental conditions including the application voltage and the application time applied to each of the tank.

The control unit of the power pack is preferably connected to the display unit to display anodization data made in the tank.

The n tanks are preferably equipped with the same sample or different samples in the n tanks.

Preferably, the n tanks are filled with the same electrolyte or different electrolytes.

Accordingly, there is an advantage in that a plurality of anodization experiments can be simultaneously implemented in one experimental device by connecting the power sources in parallel using one power source.

The present invention by the above configuration, by one power supply device can be performed simultaneously and independently different completely different anodization experiments have the effect of providing efficiency of research and maximizing the economics of the device.

1 is a schematic diagram of an anodization apparatus according to the prior art,
2 is a schematic diagram of an anodization apparatus using a parallel process according to the present invention,
3 is a schematic diagram showing an anodizing device using an parallel process according to the present invention as an electrical equivalent circuit,
4 is a schematic view showing a shape in which the power pack and the display unit are interlocked.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a schematic diagram of an anodization apparatus using a parallel process according to the present invention, Figure 3 is a schematic diagram showing an anodization apparatus using an parallel process according to the present invention as an electrical equivalent circuit, Figure 4 is a power pack and the display unit is interlocked Schematic diagram showing the shape.

As shown, the anodizing device using a parallel process according to the present invention is largely composed of a water tank 100, a power pack 200, and a display unit 300.

First, the water tank 100 will be described.

The tank is provided with different n pieces (n is 2 or more), and different electrolytes may be filled in the tank 100 if necessary. Of course, different experiments may be performed by filling the same electrolyte. The anode terminal formed in the tank 100 is connected to the anode port 210 of the power pack 200 to be described later. At this time, the positive electrode terminal of each tank is connected to each of the positive electrode port 210 formed in the power pack 200 is independently supplied with power from the power pack 200. In addition, the negative electrode terminal formed in the water tank 100 has n terminals branched in parallel from one common ground port 220 formed in the power pack 200 to be described later branched in parallel to the respective water tank 100 and the negative electrode terminal. Connected. Here, the negative electrode terminal is provided with a counter electrode such as platinum.

The power pack 200 is a power pack for power supply and is configured in a form having a rated voltage and current of X [V] and P [A], and supplies power to the n tanks 100.

N positive port 210 is formed in the power pack 100 so that the n positive port 210 is individually connected to the n positive terminals of the tank 100. In addition, one common ground port 220 is formed in the power pack 200, and the common ground ports 220 are branched in parallel from the common ground port 220 to be connected to the negative terminal of the water tank 100. do.

As described above, the voltage of the power pack 200 is paralleled or divided to induce one power pack 200 to act as a plurality of power pack power sources, such as V1, V2, V3, ... Vn in one power pack. It is the key point of the present invention that n independent power supplies are provided and formed in a structure capable of performing n independent anodization experiments, and thus independently used as a plurality of anodization experiment apparatuses.

In this case, the independent n positive ports 210 are individually attached to the on / off switch 230 so that they operate individually and independently, and the maximum voltage that each power source can use is the maximum of the power pack 200. It is obvious that the rated voltage is X [V], and it can be used by setting below the maximum rated voltage.

In addition, the power supplied from each independent power source is required to maintain a constant voltage when the experimenter is fixed to the desired voltage value, the experimenter performs a plurality of independent anodization experiments with the power pack 200 in parallel or divided Considering this case, n anode sample specimens (eg, a, b, c, ... n) for anodizing from n power sources (e.g., V1, V2, V3, ... Vn) When the amount of current flowing through is I1, I2, I3, ... In, respectively, when the sum of these total currents (I1 + I2 + I3 + ... In) is called the total current (Itotal), the total current Itotal is It is obvious that the power pack is smaller than the maximum rated current of P [A].

For each anodized sample specimen (eg, a, b, c, ... n), independent test conditions such as applied voltage and application time can be controlled by a computer-based lab or equivalent control program. Independent variable injection is performed using (not shown).

The control unit (not shown) is a control program for controlling and adjusting the power pack, which is formed inside the computer to independently control the n power sources (for example, V 1, V 2, V 3,... The application voltage and application time applied to the oxidation sample experiment are controlled independently.

Here, since the individual power supplies are operated independently of each other, even if one experiment is terminated, the other power supply has no structure at all. When one anodization experiment is terminated, the on / off switch 230 is automatically performed. The data is turned off and the obtained data is stored in a computer memory formed in the controller so that the experimenter can conveniently withdraw it at any time.

The data stored in the control unit is displayed by the display unit 300 connected to the control unit. The display unit is configured to allow the experimenter to observe data in real time with a computer monitor.

3, "R10", "R20", "R30", ... "Rn0" is a variable resistor, formed in the power pack 200 to be fixed to the desired constant voltage in each individual experiment It is designed to supply the desired constant voltage to individual experiments by freely changing the resistance value.

And resistance values such as "R1", "R2", "R3", ... "Rn" are anodization experiments consisting of metal specimens, platinum cathodes and suitable electrolytes used as anodes for oxidation. This is an illustration of an electrical equivalent circuit.

In addition, it is linked with the data acquisition system (DAQ) and the control program which consists of the Labview and the equivalent program formed in the control unit, and a graphic user interface for exchanging and displaying data in real time for n independent experiments ( Graphical User Interface (GUI) shows a display unit consisting of.

Here, the data acquisition system (DAQ) of the control unit is a well-known technology, and thus a detailed description thereof will be omitted.

4 is a schematic diagram for describing the above-described data interworking with a more detailed description. In other words, anodization data progressed in real time on a computer display screen interlocked with a control unit, which is an anodization power supply and a control (control) system, which secured n experimental data acquired in real time. It displays the voltage applied to the current, the amount of current flowing through the specimen, the temperature of the electrolyte over time, and stores it in the memory of the computer.

As described above, the greatest advantage of the present invention is that the existing one power supply device can simultaneously and independently perform different completely different anodization experiments, thereby providing research efficiency and maximizing the economics of the device. There is this.

100: tank 200: power pack
210: anode port 220: common ground port
230: on / off switch 300: display unit

Claims (5)

N tanks (n is two or more) in which an electrolyte is filled and anodization is performed for each sample mounted therein;
A power pack for supplying a predetermined amount of current and voltage to the n tanks;
N anode ports formed in the power pack and individually connected to anode terminals respectively formed in the n tanks;
One common ground port formed in the power pack and individually connected in parallel with negative terminals respectively formed in the n tanks;
And an on / off switch formed in the power pack and controlling the power supply of the n anode ports. The anodic oxidation apparatus using a parallel process according to claim 1, wherein the power pack is provided with a controller for controlling an experimental condition including an application voltage and an application time applied to each of the tanks. The anodization apparatus of claim 2, wherein the controller of the power pack is connected to a display unit to display anodization data generated in the tank. The anodization apparatus according to any one of claims 1 to 3, wherein the n tanks are equipped with the same sample or different samples. The anodic oxidation apparatus using a parallel process according to any one of claims 1 to 3, wherein the n tanks are filled with the same electrolyte or different electrolytes.

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