JPH0525700A - Method for dissolving Ni, Zn in Ni-Zn alloy plating bath - Google Patents

Abstract

(57) [Abstract] [Purpose] The present invention is applied to a Ni-Zn alloy plating bath.
The present invention relates to a method of simultaneously dissolving i and Zn. [Structure] When Ni and Zn are dissolved in a Ni-Zn alloy plating bath, the particle size is set to 1 mm or less, and the composition is set to 2
A method for simultaneously dissolving Ni and Zn in a Ni-Zn alloy plating bath, which comprises using a Ni-Zn alloy having a content of -50 wt% Ni-Zn. [Effect] The method for dissolving Ni and Zn in the Ni—Zn alloy plating bath according to the present invention is extremely fast because Ni—Zn alloy powder is used. Furthermore, for example, when used for electric Ni-Zn alloy plating, it is electrodeposited on a steel plate to remove Ni from the bath.
² +, Zn ² + ions are consumed, but this consumed Ni
If a Ni-Zn alloy that matches the composition of Zn and Zn is melted, it is easy and at the same time, a considerable amount of N consumed during plating is consumed.
There is an advantage that i ² + ions and Zn ² + ions can be replenished.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for dissolving Ni and Zn in a Ni-Zn alloy plating bath. For example, it relates to a method of simultaneously dissolving Ni and Zn in a Ni—Zn alloy plating bath when manufacturing a continuous electric Ni—Zn plated steel sheet using an insoluble anode.

[0002]

2. Description of the Related Art As a method of replenishing a plating metal in an acidic Ni-Zn electroplating bath using an insoluble anode, there are the following two methods.
Two methods are common. (A) A method of dissolving and replenishing a plating metal in the form of a soluble salt (basic carbonate, etc.) in a plating bath. (B) A method of melting and replenishing the plating metal by bringing it into direct contact with the plating bath.

The method (a) is superior to the method (b) in solubility but has a drawback of high cost, and the method (b) is low in cost but in solubility. It has the disadvantage of being inferior.

The reason (b) is that when these metals are dissolved in an acidic solution, the cathodic reaction thereof is 2H ++ 2e _.
= H ₂ reaction is indispensable, but since these metals have high hydrogen overvoltage, this reaction is hard to occur. Therefore, it is considered that the solubility is poor. Especially in the case of zinc, in addition to the above, Ni ² + ions in the plating bath are
^Since substitution precipitation occurs as ⁰ , the zinc surface is coated with metallic nickel, and the solubility of metallic zinc is hindered.

From the above, at present, there is no technique for simultaneously dissolving metallic Zn and metallic Ni into a Ni--Zn alloy plating bath.

[0006]

The present invention has solved the above-mentioned problems, and an object of the present invention is to dissolve Ni and Zn in a Ni-Zn alloy plating bath.
It is to provide a method using a Zn alloy.

[0007]

SUMMARY OF THE INVENTION The present invention is to solve the above-mentioned problems, and when supplying Ni ² + ions and Zn ² + ions to a Ni-Zn alloy plating bath, the particle size is 1 mm or less, Ni- whose composition is 2-50 wt% Ni-Zn
The present invention relates to a method for simultaneously dissolving Ni and Zn in a Ni-Zn alloy plating bath, which uses a Zn alloy.

[0008]

DETAILED DESCRIPTION OF THE INVENTION In order to facilitate understanding of the present invention, a specific and detailed description will be given.

The present invention is firstly characterized in that a Ni--Zn alloy is used as a supplementary raw material. The feature of the dissolution mechanism of Ni ² + ions in the Ni-Zn alloy plating bath and Ni-Zn alloy as a supplementary material of Zn ² + ions is that
First, Z is alloyed, and when it is dissolved in an acid bath, the hydrogen overvoltage of the alloy is relatively decreased.
Dissolution of n is promoted preferentially. Next, the residual Ni becomes extremely fine, so that the surface area is dramatically increased, whereby the dissolution of Ni is promoted, and the entire amount of the Ni—Zn alloy is dissolved in a short time. As a result, Ni ² + ions and Zn ² + ions can be supplied to the Ni-Zn alloy plating bath at the same time.

This dissolution mechanism is 2-50 wt% Ni-Zn
Common to alloys. Here, the upper limit is set to 50 wt% because it is difficult to manufacture with Ni grades higher than 50 wt% Ni because the melting point becomes high at the time of manufacturing this alloy, and then when it is dissolved in an acidic solution. If the Ni content is high,
This is because, after the preferential dissolution of Zn, the surface area of the remaining Ni becomes small and the dissolution rate as Ni becomes slow. The lower limit of 2 wt% is, for example, when used for electroplating, the Ni concentration in the plating bath is 2 to 50 g.
This is because Ni is used as / l, and Ni is less practical than 2 wt% for melting, which is not practical.

For example, Ni for dissolving Ni ² + ions and Zn ² + ions in an electric Ni-Zn alloy plating bath is used.
The composition of the —Zn alloy is preferably 2 to 50% Ni—Zn.

The second feature of the present invention is that the grain size of the alloy is 1 mm or less. Ni ² + ions of Ni-Zn alloy plating bath is 25~60g / l, Zn ² +
The amount of ions is also about 25 to 60 g / l. When attempting to dissolve the Ni-Zn alloy in this bath, the Ni in the bath is
^A so-called cementation reaction occurs in which ² + ions are substitutionally deposited as nickel metal on the surface of the Ni—Zn alloy. When the grain size of the Ni-Zn alloy is larger than 1 mm,
The cementation reaction slows the dissolution rate of the Ni-Zn alloy, but if the particle size is 1 mm or less, Ni-Zn alloy
The dissolution rate of the Zn alloy is not stagnant but is promoted to the contrary. Therefore, the grain size of the Ni-Zn alloy is preferably in the range of 1 mm or less. The particle size may be adjusted by either crushing or atomizing.

Using Ni-Zn alloy as a raw material, Ni-Zn
When Ni ² + ions and Zn ² + ions are dissolved in the system alloy plating bath, the liquid property of the Ni—Zn system alloy plating bath is an acidic solution, such as H ₂ SO ₄ or HCl.

Regarding the acidity of the plating bath for melting the Ni-Zn alloy, the lower the pH, the more advantageous it is. However, if the pH is too low, the electric current may be increased when the Ni-Zn alloy is used for electroplating. Since efficiency may decrease, p
H is preferably 0.8 to 2.0.

The higher the temperature at which the Ni-Zn alloy is melted, the more advantageous it is, but when it is used for electroplating, for example, a sufficient bathing rate can be obtained even at a normal bath temperature of 50 to 60 ° C. ..

[0016]

EXAMPLES Examples of the present invention will be described below. The test conditions are as follows, and as a solution, an insoluble anode is used and Ni having a general composition when performing high-speed plating is used.
A Zn-based alloy plating bath was used. 1. Basic conditions of dissolution liquid Basic composition ZnSO ₄ 7H ₂ O 220 g / l (Zn ² +
Ion, 50 g / l) NiSO ₄ .6H ₂ O 224 g / l (Ni ² + ion, 5
0 g / l) Acidity pH = 0.8-2.0 Bath temperature 50,60 degrees

2. Ni-Zn alloy shape shot, powder composition 2-50 wt% Ni-Zn alloy

3. Test method Put the above liquid 1 in a beaker and put it in a constant temperature water bath for 5
Ni-Zn alloy was added to this while maintaining the temperature at 0 and 60 ° C.
The dissolution test of the Ni-Zn alloy was performed by adding 0 g. N
The amount of i-Zn dissolved was determined by analyzing the concentrations of Ni ² + and Zn ² + ions in the solution. During the dissolution of the Ni-Zn alloy, the pH of the bath changes, so sulfuric acid is continuously replenished,
The liquid pH was maintained at the initial value. The solution was stirred at 250 γpm so that the pH could quickly reach the initial value. The results of the dissolution test are shown in FIG.

[0019]

Example 1 Under the above conditions, the acidity was adjusted to pH = 0.8. As shown by 1-1 in FIG. 1, 50 g of the 13 wt% Ni-Zn alloy having a particle size of 43 μm or less was completely dissolved in 6 minutes.

[0020]

EXAMPLE 2 In solution basic conditions, acidity (H ₂ SO ₄ acid) to pH = 1.5, a bath temperature of 60 ℃, 13wt% Ni-Zn alloy powder was less particle size 43μm by grinding 50 g was subjected to a dissolution test. As shown by 1-2 in FIG. 1, the total amount of the 13 wt% Ni—Zn alloy was dissolved in the melting time of 15 minutes.

[0021]

Example 3 Under the same conditions as in Example 1, the acidity was adjusted to pH =
The particle size of the 13 wt% Ni-Zn alloy was set to 0.5.
It was set to 5 mm. As shown by 1-3 in FIG. 1, 50 g of the total amount was dissolved in the dissolution time of 30 minutes.

[0022]

Example 4 Under the same conditions as in Example 1, the acidity was adjusted to pH =
The particle size of the 13 wt% Ni-Zn alloy is set to 1.5 and is set to 23.
It was 2 μm. As shown by 1-4 in FIG. 1, 50 g of the total amount was dissolved in 25 minutes.

[0023]

Example 5 Under the same conditions as in Example 1, the composition of the Ni—Zn alloy was 50 wt% Ni—Zn and the grain size was 43 μm.
Below. As shown by 1-5 in FIG. 1, in the dissolution time of 28 minutes, the total amount of 50 g used was dissolved.

[0024]

Example 6 Under the same conditions as in Example 1, the composition of the Ni—Zn alloy was 2 wt% Ni—Zn and the particle size was 43 μm or less. As shown by 1-6 in FIG. 1, the total amount of 50 g used was dissolved in the dissolution time of 25 minutes.

[0025]

Example 7 Under the same conditions as in Example, the acidity was adjusted to pH =
0.8, the Ni-Zn alloy composition is 2 wt% Ni,
5 wt% Ni, 10 wt% Ni, 25 wt% Ni, 50
The grain size of the Ni-Zn alloy with wt% Ni is 1 mm, 2
The solution was dissolved in 32 μm, 43 μm and 5 μm. All of these dissolved a total of 50 g used with a dissolution time of 6 minutes.

[0026]

Comparative Example 1 13 wt% Ni-Zn under the conditions of Example 1
The grain size of the alloy was 2 mm and 7 mm. 2-1 and 2 of FIG.
-2. When the particle size was 2 mm, 17 g of 50 g used was dissolved, and when the particle size was 7 mm, 5 g was dissolved in a dissolution time of 3 hours. Therefore, 33 mm remains at 2 mm,
At 7 mm, 45 g remained, and the total amount could not be dissolved.

[0027]

Comparative Example 2 Under the conditions of Example 1, 50 g of metallic Zn and metallic nickel having a particle diameter of 7 mm were used for melting. Three
In the melting time of 7 hours, 7 g of metallic zinc was dissolved, 43 g was left, and 0.03 g of metallic nickel was dissolved.
g remained. It is shown in 2-3 and 2-4 of FIG.

[0028]

Comparative Example 3 Under the conditions of Example 1, commercially available Ni powder, Zn
The powder was used for dissolution. As shown by 2-5 and 2-6 in FIG. 1, in a dissolution time of 3 hours, 16 g of Ni powder was dissolved, 34 g of Zn powder was left, and 23 g of Zn powder was dissolved.
7 g remained.

[0029]

Comparative Example 4 Under the conditions of Example 1, commercially available Ni powder and Zn
The powder was mixed so as to have a composition of 13 wt% Ni-Zn, and the total amount was 50 g, which was then subjected to dissolution. 2-7 in FIG.
As shown in, after 3 hours of dissolution, 37g dissolved, 13g
Remained.

[0030]

As described above, according to the present invention,
The method of dissolving Ni and Zn in the Ni-Zn alloy plating bath is extremely fast because Ni-Zn alloy powder is used.

Furthermore, for example, in the case of using for electric Ni-Zn alloy plating, Ni ² + ions and Zn ² + ions are consumed from the bath by electrodeposition on a steel plate.
If a Ni-Zn alloy matching the composition of i and Zn is melted,
There is an advantage that the Ni ² + ions and Zn ² + ions consumed during plating can be replenished in a considerable amount at the same time.

[Brief description of drawings]

FIG. 1 shows the dissolution speed, which is an embodiment of the present invention and a comparative example.

Claims (1)

Claims: 1. When a Ni-Zn alloy plating bath is replenished with Ni ² + ions and Zn ² + ions, the particle size is 1 mm.
A method for dissolving Ni and Zn in a Ni-Zn alloy plating bath is described below, in which a Ni-Zn alloy having a composition of 2 to 50 wt% Ni-Zn is used.