JP5516702B2 - Method for temper rolling of Ni-plated steel sheet with excellent degreasing properties - Google Patents

Description

  The present invention relates to a temper rolling method for a Ni-plated steel sheet having excellent degreasing properties.

  In general, cold-rolled and annealed steel sheets are prepared for the purpose of preventing buckling and stretcher strain, imparting the necessary mechanical properties, stabilizing the shape such as flattening the surface, and imparting surface roughness suitable for the application. It is common to perform quality rolling. In the temper rolling, a water-soluble tempered rolling liquid is used except for the tin plate and other special cases, and the water-soluble tempered rolling liquid is also used in the manufacturing process of the cold-rolled steel sheet.

  Cold-rolled steel sheets are shipped in a state in which rust-preventing oil is applied in the final process for the purpose of preventing rust generation and improving formability. For customers such as automobiles and home appliances, molding is performed on the desired part shape such as pressing, and in most cases, it is degreased with an alkaline degreasing solution or solvent, and is coated or plated, so it is good for steel sheets Degreasing properties are required.

  In particular, steel plates for automobiles are generally subjected to a chemical conversion treatment such as a phosphate treatment as a coating base treatment after forming and degreasing, and then a cationic electrodeposition coating is further performed. In order to develop an excellent appearance and post-coating corrosion resistance by electrodeposition coating, it is necessary to form a chemical conversion treatment as a base coating as a normal film. In order to form a good chemical conversion film, it is necessary to form crystal nucleation base points in the chemical conversion pretreatment, and to subsequently grow a chemical conversion film crystal in the chemical conversion process.

In the case of producing a cold-rolled steel sheet by a continuous annealing method, a trace amount Ni plating technique called flash plating has been proposed in order to develop good chemical conversion treatment properties (Patent Documents 1 and 2). In patent document 1, the technique which makes metal Ni adhere 0.3-10 mg / m < ² > on a cold-rolled steel plate is proposed. The phosphate crystal grows with the cathode part on the surface of the steel plate as the nucleus, but due to the potential difference between Ni and Fe partially deposited on the surface of the steel plate, an electrically non-uniform state is formed and Ni adheres. The part which becomes a cathode part becomes a starting point of phosphate crystal formation. And the improvement effect of chemical conversion property and corrosion resistance after coating is acquired. Further, Patent Document 2 proposes a technique in which Ni oxide and / or Ni hydroxide adhere to 1 to 150 mg / m ^{2 in} terms of Ni element weight on a cold-rolled steel sheet. By this technique, the chemical conversion treatment property that does not respond sensitively to changes with time of the chemical conversion bath components is expressed.

  Ni flash plating applied to a cold-rolled steel sheet manufactured by a continuous annealing method has an effect of improving the chemical conversion property, but a decrease in degreasing property may be pointed out. When Ni oxide or Ni hydroxide is formed on the surface, the affinity with oil is strong, so when a degreasing deterioration factor component such as rust preventive oil is mixed in the degreasing liquid with time, or in the air In some cases, such as when the pH is lowered due to the influence of carbon dioxide, the rust preventive oil is hardly removed in the degreasing step due to the influence of the degreasing liquid fluctuation in the degreasing step.

As a technique for suppressing such degreasing deterioration, in Patent Document 3, a metal Ni layer is provided on the ground steel side of the steel sheet surface, a nickel hydroxide layer is provided on the outermost layer, and the Ni existing ratio in the outermost layer is 75 to 95 atm. %, And further cold-rolled steel sheet with 1 to 100 mg / m ² of Ni deposited in terms of element weight has been proposed. The metal Ni formed on the base iron side shows good reactivity in the chemical conversion treatment after degreasing, and the ratio of the metal Ni in the lower layer facing the outermost layer to 95 atm% or less is controlled by the nickel hydroxide present in the surface layer. Degreasability due to increased sensitivity to rust-preventing oil by preventing Ni from being excessively sensitive to chemical conversion solution and controlling Ni content in the surface layer to 75 atm% or more. Decline can be prevented. Moreover, in patent document 4, the roughness of a steel plate shall be 1.5 micrometers or less by Ra, and the organic substance adhesion amount to the steel plate of the temper rolling liquid containing 1-15% of water-soluble organic substance shall be 20-80 mg / m < ² >. A method for manufacturing a cold-rolled steel sheet has been proposed. If it exceeds 80 mg / m ² , not only the degreasing property is deteriorated but also organic gumming tends to occur. When it is less than 20 mg / m ² , the behavior becomes close to dry rolling, and the roll surface is abraded so that the rolling workability is greatly reduced. Examples of water-soluble organic substances having an organic adhesion amount include rust inhibitors such as carboxylic acids and amine salts, and surfactants.

  However, it is very difficult to stably control and manufacture Ni deposited on the surface of the steel sheet in the form of metal Ni, Ni oxide, and Ni hydroxide in a layered manner, and the load on the manufacturing process is large. In addition, controlling the amount of temper rolling fluid containing water-soluble organic matter to the steel sheet to be controlled within this range is a limited range of conditions, and loss when the amount of adhesion due to fluctuations in manufacturing conditions is outside the range. Have the problem of growing. Furthermore, the problem that the degreasing property is deteriorated depending on the combination of the water-soluble organic substance added to the temper rolling liquid and the rust preventive oil applied to the upper layer has not been solved.

  On the other hand, various studies have been made on water-soluble tempered rolling fluids. Conventionally, water-soluble tempered rolling fluid has an appropriate coefficient of friction according to the rolling rate of the steel sheet, has excellent quality of foreign matter and wear powder on the steel sheet after annealing, and prevents post-temper rolling. It is required to have rust prevention properties up to the rust oil coating step and to be excellent in the degreasing properties and chemical conversion treatment properties of the cold-rolled steel sheet after the rust oil coating. In Patent Document 5, an emulsion-type tempered rolling fluid containing 0.5 to 2.0% by volume of rolling oil and 0.05 to 0.5% by volume of an alkanolamine salt of a dibasic acid having 8 to 16 carbon atoms was used. A rolling method has been proposed. This is a technology that enables temper rolling at a high pressure reduction rate of 3 to 10% while having rust prevention properties, but sufficient degreasing has not been confirmed, and a degreasing liquid in the degreasing process of customers. Under the influence of fluctuation, the rust preventive oil may be difficult to remove in the degreasing process. Patent Document 6 proposes a tempered rolling fluid containing a dibasic acid having a cyclohexane ring. This has the effect of suppressing the generation of black adhesive substances that are likely to occur when passing through tension levelers and bridal rolls when the moisture of the temper rolling liquid has dried to some extent, and the occurrence of white turbidity on the steel sheet surface after the application of rust preventive oil. There is going to be. Patent Document 7 proposes a tempered rolling fluid composed of a mixed carboxylic acid composed of benzothiazolylthioalkylene carboxylic acid and aliphatic carboxylic acid and an amine, which suppresses surface scratches during rolling and disturbs dimensional accuracy. There is an effect that it does not occur. Patent Document 8 proposes a temper rolling agent composed of a specific benzotriazole compound, phenoxyalkyl carboxylic acid, aliphatic carboxylic acid, surfactant, and alkali agent. In addition to the excellent rust prevention effect, There is an effect that it is possible to prevent generation of gum-like substances (gum-up) due to mixing. However, these are all degreased when combined with Ni adhering to the surface of the cold-rolled steel sheet to be treated for chemical conversion, especially with respect to the degreasing effect when affected by the degreasing liquid fluctuation in the degreasing process as described above. Insufficient confirmation has been made regarding the properties and chemical conversion treatment properties, and some rust preventive oil components remain because sufficient degreasing properties cannot be obtained when subjected to fluctuations in the degreasing process in the consumer. In the subsequent chemical conversion treatment step, a normal chemical conversion treatment film is not formed.

Japanese Patent Laid-Open No. 56-116883 JP 59-159989 A JP-A-7-278843 Japanese Patent Laid-Open No. 2003-33802 JP-A-6-1992 JP-A-9-302368 JP 2000-87073 A JP 2001-288492 A

  The present invention solves the problems of the prior art as described above, and when a degreasing deterioration factor component such as rust-preventing oil is mixed in the degreasing liquid in the degreasing process of the customer, particularly over time, or in the air. Even when there is a degreasing liquid fluctuation, such as when the pH is lowered due to the influence of carbon, etc., it has stable good degreasing properties without being affected by those effects, and it is excellent in the chemical conversion treatment step performed subsequent to the degreasing step. It aims at providing the temper rolling method of the Ni-plated steel plate excellent in the degreasing property which can obtain the cold-rolled steel plate which has chemical conversion treatment property.

In order to solve the above-mentioned problems, the present inventors diligently studied various combinations of temper rolling liquid compositions.
As a result, by adding an alkaline pH adjuster that completely neutralizes the acid contained in the water-soluble anticorrosive agent, the free alkaline polar component of the alkaline pH adjuster is adsorbed with the polar component in the rust preventive oil. Prevents the strong adsorption of the polar component in the rust preventive oil and the Ni oxide or Ni hydroxide formed on the surface of the steel plate, and demonstrates the effect that the rust preventive oil is easily removed in the degreasing process. I found out.

  In order to exert this effect, a water-soluble adjustment containing an alkaline pH adjuster containing a water-soluble rust inhibitor and water as main components and a free alkali component in a specific range that neutralizes the acid contained in the water-soluble rust inhibitor. It has been found that by temper rolling using a temper rolling liquid, a Ni-plated cold-rolled steel sheet having excellent degreasing properties and chemical conversion treatment properties can be obtained without being affected by fluctuations in the degreasing liquid.

The present invention has been completed based on such knowledge, and the gist of the present invention is as follows.
“(1) When temper-rolling a Ni-plated steel sheet, by mass%, water-soluble rust preventive agent: 1 to 6%, alkanolamine-based alkaline pH adjuster: 0.8 to 5.5%, surfactant : 0.005 to 1%, the remainder consists of water and inevitable impurities, and the total amount of the water-soluble soot preparation, alkanolamine-based alkali pH adjuster and surfactant is 3 to 8% by mass, A Ni-plated steel sheet excellent in degreasing properties, characterized by using a tempered rolling liquid containing an alkanolamine-based alkali pH adjuster in an amount of 2 to 4 mol per mol of acid contained in a rust inhibitor. Temper rolling method (2) The degreasing property of (1), wherein the alkanolamine-based alkali pH adjuster is one or a mixture of two of monoisopropanolamine and diisopropanolamine Excellent Ni-plated steel temper rolling method (3) The water-soluble rust inhibitor is one or a mixture of two or more of benzoic acid derivatives, organic carboxylic acids, and organic chelate nitrogen-containing compounds. (1) or (2) A temper rolling method for a Ni-plated steel sheet having excellent degreasing properties, (4) The surfactant is a nonionic surfactant (1) or (2) or (3) a temper rolling method for a Ni-plated steel sheet having excellent degreasing properties, (5) the temper rolling solution according to any one of (1) to (4) is a water-soluble rust preventive. The total content of the agent, the alkanolamine-based alkaline pH adjuster and the surfactant is 5 to 50% by mass, and the remainder is obtained by diluting water and the temper rolling stock solution, which is an unavoidable impurity, with water. Degreasability characterized by using this temper rolling liquid Excellent Ni plated steel sheet temper rolling method. "It is.

  That is, in the present invention, in order to prevent strong adsorption of the polar components of Ni oxide or Ni hydroxide and rust preventive oil, and to easily remove the rust preventive oil in the degreasing process, one of the alkaline pH adjusters is used. In order to weaken the adsorption of the polar component of the rust preventive oil and the Ni oxide or Ni hydroxide on the surface of the steel sheet, the free alkali polar component of the part is 2 to 4 times mol to 1 mol of the acid contained in the water-soluble rust inhibitor. A tempered rolling liquid containing an alkaline pH adjuster is used.

  The temper rolling liquid of the present invention has a stable good degreasing property without being affected by the degreasing liquid fluctuation, and excellent chemical conversion processability even in the chemical conversion process performed following the degreasing process. Cold-rolled steel sheets with high-temperature properties, so that after machining or welding to automotive parts or home appliance parts, processing oil or rust preventive oil is degreased to form a base treatment. It is suitable as a temper rolling method for a Ni-plated steel sheet having excellent degreasing properties to be treated.

It is a figure which shows the influence of the molar multiple of the alkanolamine type | system | group pH adjuster with respect to the acid contained in a water-soluble rust preventive agent.

The contents of the present invention will be described in detail below.
The temper rolling liquid used in the present invention contains an alkaline pH adjuster containing a water-soluble rust preventive agent and water as main components and a free alkali component in a specific range with respect to the contained acid.
Water as the main component is not particularly limited, and pure water, deionized water, tap water, etc. can be used, but various ions present in the water are effective for water-soluble rust preventives, alkaline pH adjusters and surfactants. Pure water or deionized water is preferred because it may have an effect.

The water-soluble rust preventive agent may be any one that has been developed for conventional water-soluble temper rolling liquids or wet temper rolling applications. For example, a mixture of a nitrite such as sodium nitrite and an ethanolamine derivative, benzoic acid Nitrogen-containing compounds such as benzoic acid derivatives such as sodium benzoate, benzotriazole compounds such as 1-hydroxybenzotriazole, 1-hydroxytolylbenzotriazole, 5-methylbenzotriazole and carboxybenzotriazole, and indazole compounds such as imidazole and benzindazole And organic carboxylic acids.
However, when nitrite and alkanolamine coexist, it is known that nitrosamine is produced by reaction, and caution is required because it has a negative effect on the human body.

  Examples of organic carboxylic acids include aliphatic dibasic acids such as succinic acid, adipic acid, azelaic acid, sebacic acid, undecanoic acid, and suberic acid, and aromatic dicarboxylic acids such as p-nitrobenzoic acid and cyclohexanedicarboxylic acid. Can be mentioned. These can be used alone or in combination.

  Organic chelate nitrogen-containing compound rust preventives such as hydroxybenzotriazole compounds, methylbenzotriazole compounds and indazole compounds react with iron on the steel sheet surface to form an insoluble iron chelate film, and thus have a large rust preventive effect. In addition, benzoic acid derivatives and organic carboxylic acids have a large rust prevention effect because they promote the formation of oxide films and suppress the anode reaction. A mixture of a nitrite such as sodium nitrite and an ethanolamine derivative chemisorbs on the surface of the steel sheet and suppresses the anode reaction.

  The concentration of these water-soluble anticorrosive agents is preferably in the range of 1 to 6% by mass, and if it is less than 1% by mass, the anticorrosive power imparted to the steel sheet is not sufficient, and if it exceeds 6% by mass, the alkaline pH adjuster used in combination is not sufficient. Since the addition amount with respect to a water-soluble rust preventive agent falls, in addition to the degreasing property of a rust preventive oil falling as mentioned later, gum-up property falls, and it is not desirable.

  Since the rust preventive agent such as aliphatic dibasic acid or aromatic dicarboxylic acid is acidic when dissolved in water, it is necessary to maintain the pH of the temper rolling solution at neutral or higher. An alkali pH adjuster is used as the neutralizer.

  Examples of the alkaline pH adjuster include ammonia, potassium hydroxide, and Na hydroxide, but these are not preferable from the viewpoint of workability and adverse effects on the steel sheet surface, and amines are generally used.

Examples of the amines used as the alkaline pH adjuster include alkanolamines, lower alkylamines, lower alkylalkanolamines, polyamines, and cyclic amines.
Of these, alkanolamine is particularly preferred. Examples of the alkanolamine include ethanolamine, isopropanolamine, diethanolamine, diisopropanolamine, dibutanolamine, and triethanolamine. The amino group side, which is a hydrophilic group, adsorbs to the surface of the steel sheet to have a rust prevention effect and a pH adjustment effect. However, since the tendency to emulsify in an aqueous solution is exhibited when the hydrophobicity increases, it is necessary to confirm the liquid stability when the number of carbon atoms in the hydrocarbon group exceeds 6.
The concentration of these alkanolamine-based pH adjusters is preferably in the range of 0.8 to 5.5% by mass. If the concentration is less than 0.8% by mass, the amount of the alkali pH adjuster added to the water-soluble rust inhibitor is reduced. The degreasing property of the rust preventive oil decreases, and if it exceeds 5.5% by mass, the amount of the alkaline pH adjuster added to the water-soluble rust preventive agent is too large, which is not desirable because the rust preventive power imparted to the steel sheet becomes insufficient. .

  The alkaline pH adjuster needs to be added in an amount of 2 to 4 mols per mol of acid in the water-soluble rust inhibitor. By adding an alkaline pH adjusting agent that completely neutralizes the acid contained in the water-soluble anti-corrosive agent, the free alkaline polar component of the alkaline pH adjusting agent is adsorbed with the polar component in the anti-rust oil to prevent This prevents the polar component in the rust oil and the Ni oxide or Ni hydroxide formed on the steel sheet surface from being firmly adsorbed. Therefore, as shown in FIG. 1, in order to demonstrate the good degreasing property of a rust preventive oil in a degreasing process, 2 times mol or more is required. And when favorable degreasing property is ensured, the chemical conversion process processed at a subsequent process can also be processed stably. On the other hand, as shown in FIG. 1, when an alkali pH adjuster exceeding 4 times mol is added, good degreasing property is maintained, but the effect is saturated, which is not preferable from an economical point of view. Since the ability of the rust preventive agent to be adsorbed on the surface of the steel sheet is reduced, the rust prevention ability is reduced, which is not preferable.

  Surfactant improves the uniform application of liquid on the steel sheet surface (paintability), improves lubricity by reducing the friction coefficient during rolling, improves the cleaning performance to keep the steel sheet surface clean, and foams during liquid handling and application. It is added for the purpose of suppressing defoaming, improving gum-up resistance, and improving direct paintability. Gum-up is a phenomenon in which an adhesive substance composed of a temper rolling liquid component and an antirust oil component is generated, and the adhesive substance entraps and deposits foreign matters such as iron powder. There are various surfactants such as cationic surfactants, anionic surfactants, nonionic surfactants, etc., but without reducing the effect of water-soluble rust preventives and alkaline pH adjusters, uniform coating properties, lubrication Nonionic surfactant having both lipophilic group and hydrophilic group structures is desirable from the viewpoint of improving the property, detergency, antifoaming property and gum-up resistance.

  Nonionic surface activity includes polyoxyethylene alkyl ether, polyoxyethylene alkylphenyl ether, polyoxyethylene alkylamine, polyoxyalkylene alkyl ether, polyoxyethylene glycol, polyoxyethylene polyoxypropylene glycol block copolymer and the like.

  The surfactant is preferably 0.005 to 1% by mass of the total liquid amount. When the amount is less than 0.005% by mass of the total liquid amount, the effect is insufficient, and when it exceeds 1% by mass, the effect is not only saturated but also the effect of improving the rust resistance by the rust inhibitor is lowered, which is not desirable.

  The total concentration of the water-soluble rust inhibitor, alkanolamine-based alkali pH adjuster, and surfactant, which are the active ingredients of the present case when the present temper rolling liquid is actually used in a temper rolling mill, is 3 to 8% by mass. Is preferably used. Outside the above range, the residual organic amount of the temper rolling liquid remaining on the surface of the steel sheet, which will be described later, is not obtained, and lubrication of the temper rolling is affected. Further, if it is less than 3% by mass, the rust-proofing property is lowered, and if it exceeds 8% by mass, the effect is saturated, and the effective component may be built up on a roll of a line and transferred to a steel sheet, affecting the quality.

  When the temper rolling liquid is carried from the manufacturer to the temper rolling mill, it is preferable that the active ingredient of the present case is concentrated and carried, and diluted to an appropriate concentration with water for use. At that time, the total of the active ingredients (water-soluble rust inhibitor, alkaline pH adjuster, nonionic surfactant) of the tempered rolling stock solution carried into the temper rolling mill is the liquid stability and solubility. 8-50 mass% is desirable from an economical viewpoint.

  In addition to the water-soluble rust preventive agent, alkaline pH adjuster, and surfactant, the temper rolling liquid and its undiluted solution are various organic or inorganic types within the range that does not impair the purpose and effect thereof. An additive may be included. Examples of such additives include bactericides to prevent mold and corrosion due to contact with air during long-term storage and storage in tanks, extreme pressure additives to prevent seizure during rolling, There are viscosity modifiers for controlling liquid properties.

The rolled product, which is an object using the temper rolling solution of the present invention, is a cold-rolled steel sheet such as ordinary carbon steel, high carbon steel, and high-tensile steel sheet, and in particular, a small amount of Ni is adhered to the steel sheet surface. A cold-rolled steel sheet is preferred. The effect of improving chemical conversion properties and rust prevention properties can be obtained by attaching Ni. Even in the low adhesion amount range where the adhesion amount is approximately 0 to ² mg / m ² , the improvement effect of the chemical conversion treatment property and the rust prevention property is recognized, but the adhesion amount range of 3 to 15 mg / m ² is the chemical conversion treatment property and the rust prevention property. Desirable from a viewpoint. Even if the Ni adhesion amount exceeds 15 mg / m ² , there is an effect of improving the chemical conversion treatment property and the rust prevention property to a certain extent, but as will be described later, the polar component in the rust prevention oil and the Ni oxide or It is also not preferable from the economical viewpoint that the degreasing property considered to be due to an increase in the adsorptive power with Ni hydroxide becomes significant and the amount of Ni adhesion increases. The Ni adhesion method may be any method such as chemical plating, electroplating, and vapor phase plating, and is not particularly limited. For example, it can be formed by electroplating with a plating solution made of nickel sulfate hexahydrate. The amount of Ni adhesion can be easily controlled by increasing or decreasing the amount of plating energization. For example, in the case of electric Ni plating, when Ni ions are sufficiently supplied to the surface of the steel sheet to be plated, metal Ni is deposited, but when Ni ions are insufficiently diffused (or insufficiently supplied), the consumption of protons causes an interface. It is considered that Ni hydrated oxide is formed because the pH at the part increases. Therefore, it is considered that Ni formed on the surface of the steel sheet is not only metal Ni but also a mixture of oxidized Ni and oxidized hydroxide. For this reason, it is considered that the removal of the rust preventive oil in the degreasing step becomes difficult and the degreasing property is lowered by the adsorption force between the polar component in the rust preventive oil and Ni oxide or Ni hydroxide.

  The rolling method of the present invention using the tempered rolling liquid, as in the prior art, has the rolling conditions such as rolling load, rolling roll surface finish, rolling speed, etc. depending on the required mechanical properties and surface roughness suitable for the application. What is necessary is just to select and the existing rolling mills, such as a single stand rolling mill and a 2 stand rolling mill, can be used for a rolling mill. A bright roll or a dull roll having a different surface roughness can be used to finish the rolling roll to the required surface roughness. The temper rolling liquid is sprayed and adhered to the rolling roll by spraying, so that it is supplied to the gap between the steel plate and the roll during rolling of the steel plate and is uniformly rolled.

Residual organic matter of temper rolling solution remaining on the surface of the steel sheet after being rolled, the range of per side 90mg / ^{m 2} ~300mg / ^m 2 is preferred. If it is less than 90 mg / m ² per side, the rust prevention effect on the steel sheet surface will be insufficient, and the effect of preventing the polar component in the rust prevention oil and the steel sheet surface from adsorbing firmly will be insufficient, resulting in sufficient degreasing properties. Since it is not possible, it is not preferable. If it is 90 mg / m ² or more, good degreasing properties are exhibited, but it is more preferably 100 mg / m ² or more from the viewpoint of stable degreasing properties that are not affected even when the degreasing process is greatly varied. Also, it it is a rare that residual organic material of the water-soluble temper rolling solution remaining on the surface of the steel sheet is more than 300 mg / m ² under normal operating conditions, also rust resistance improved as exceeds 300 mg / m ² Owing to saturation of the effect and a large amount of organic residue remaining on the surface of the steel sheet, operational problems such as generation of pushing scratches on the surface of the steel sheet due to build-up of the organic residue on the roll when contacting the roll after rolling occur. This is not preferable. To measure the amount of residual organic matter in the water-soluble tempered rolling liquid remaining on the surface of the steel sheet after being rolled, for example, a cut sheet sample is prepared from the temper-rolled steel sheet and immersed in an organic solvent such as ethanol or acetone. It is possible to extract the tempered rolling liquid, perform liquid chromatography analysis on the extracted liquid, and quantify each component constituting the rolling liquid. Alternatively, measure the absorbance of the liquid that has been washed on the surface of the steel sheet using ion-exchanged water, measure the concentration using a calibration curve prepared in advance using organic substance-containing water with a known concentration, and determine the amount from the liquid volume and the washed area. Is possible.

  The cold-rolled steel sheet rolled using the temper rolling solution is generally coated with rust-preventing oil after temper rolling to ensure rust prevention. As the rust preventive oil to be applied, known rust preventive oils conventionally used are used. Examples thereof include those containing a mineral oil composed of petroleum hydrocarbons as a main component and containing rust preventive additives such as petroleum sulfonic acid sodium salt, petroleum sulfonic acid barium salt, petroleum sulfonic acid calcium salt, and fatty acid barium salt.

Hereinafter, the present invention will be specifically described with reference to Examples and Comparative Examples.
Based on a tempered rolling solution in which a salt and a surfactant composed of an amine pH adjuster in an amount equivalent to the mol amount of the acid contained in the water-soluble rust preventive agent are dissolved in water, the amount of the amine pH adjuster added is Various liquids added in excess were prepared (Examples 1 to 10 and Comparative Examples 1 to 12). Each temper rolling liquid was prepared by adding each component to 70 ° C. water while stirring and dissolving the mixture uniformly, and then cooling to room temperature. In addition, each component used the commercially available reagent and the following was used about surfactant.

・ Polyoxyethylene alkyl ether surfactant Lion Leocol SCI

・ Polyoxyethylene polyoxypropylene glycol block copolymer surfactant Newpol PE64 manufactured by Sanyo Chemical Industries

・ Polyoxyalkylene alkyl ether surfactant NAROACTY CL-100 manufactured by Sanyo Chemical Industries

<Liquid A1: Tempered rolling stock solution with 2 times mol of amine to acid>
Deionized water 73.2% by mass
Aqueous rust inhibitor p-nitrobenzoic acid 9.9% by mass
1-hydroxybenzotriazole 7.6% by mass
Aqueous rust inhibitor total 17.5% by mass
Alkanolamine-based alkaline pH adjuster Isopropanolamine 8.8% by mass
(Alkaline pH adjuster 2 times mol for acid)
Surfactant Polyoxyethylene alkyl ether surfactant 0.5% by mass
Stock solution of temper rolling liquid Active ingredients Total 26.8% by mass
Tempered rolling stock solution having the above composition.

<Liquid A2: Tempered rolling stock solution having 4 times mol of amine to acid>
Deionized water 67.3% by mass
Aqueous rust inhibitor p-nitrobenzoic acid 9.1% by mass
1-hydroxybenzotriazole 7.0% by mass
Aqueous rust inhibitor total 16.1% by mass
Alkanolamine alkali pH adjuster Isopropanolamine 16.1% by mass
(4 times mol of alkaline pH adjuster for acid)
Surfactant 0.5% by mass of polyoxyethylene alkyl ether surfactant
Stock solution of temper rolling liquid Active ingredients Total 32.7% by mass
Tempered rolling stock solution having the above composition.

<Liquid A3: Tempered rolling stock solution with 0.05% surfactant amount>
Deionized water 73.6% by mass
Aqueous rust inhibitor p-nitrobenzoic acid 9.9% by mass
1-hydroxybenzotriazole 7.6% by mass
Aqueous rust inhibitor total 17.5% by mass
Alkanolamine type
Alkaline pH adjuster Isopropanolamine 8.8% by mass
(Alkaline pH adjuster 2 times mol for acid)
Surfactant Polyoxyethylene alkyl ether surfactant 0.05% by mass
Stock solution of temper rolling liquid Active ingredients Total 26.35% by mass
Tempered rolling stock solution having the above composition.

<Liquid A4: Tempered rolling stock solution with 2% surfactant amount>
Deionized water 72.2% by mass
Aqueous rust inhibitor p-nitrobenzoic acid 9.7% by mass
1-hydroxybenzotriazole 7.5% by mass
Aqueous rust inhibitor total 17.2% by mass
Alkanolamine alkali pH adjuster Isopropanolamine 8.6% by mass
(Alkaline pH adjuster 2 times mol for acid)
Surfactant Polyoxyethylene alkyl ether surfactant 1.96% by mass
Stock solution of temper rolling liquid Active ingredients Total 27.76% by mass
Tempered rolling stock solution having the above composition.

<Liquid B1: Tempered rolling stock solution with equimolar amounts of acid and amine> Note: Deionized water below the lower limit of amine-based pH adjusting agent 76.6% by mass
Aqueous rust inhibitor p-nitrobenzoic acid 10.3% by mass
1-hydroxybenzotriazole 8.0 mass%
Aqueous rust inhibitor total 18.3% by mass
Alkanolamine alkali pH adjuster Isopropanolamine 4.6% by mass
(1 times mol of alkaline pH adjuster for acid)
Surfactant 0.5% by mass of polyoxyethylene alkyl ether surfactant
Stock solution of temper rolling liquid Active ingredients Total 23.4% by mass
Tempered rolling stock solution having the above composition.

<Liquid B2: Tempered rolling stock solution with 1.5 times mol of amine to acid>
Deionized water 74.9% by mass
Water rust inhibitor p-nitrobenzoic acid 10.1% by mass
1-hydroxybenzotriazole 7.8% by mass
Aqueous rust inhibitor total 17.9% by mass
Alkanolamine alkaline pH adjuster Isopropanolamine 6.7% by mass
(Alkaline pH adjuster for acid 1.5 times mol)
Surfactant 0.5% by mass of polyoxyethylene alkyl ether surfactant
Stock solution of temper rolling liquid Active ingredients Total 25.1% by mass
Tempered rolling stock solution having the above composition.

<Liquid B3: Tempered rolling stock solution with 4.5 times mol of amine to acid>
Deionized water 66.0% by mass
Aqueous rust inhibitor p-nitrobenzoic acid 8.9% by mass
1-hydroxybenzotriazole 6.9% by mass
Aqueous rust inhibitor total 15.8% by mass
Alkanolamine-based alkaline pH adjuster Isopropanolamine 17.7% by mass
(Alkaline pH adjuster 4.5 times mol for acid)
Surfactant 0.5% by mass of polyoxyethylene alkyl ether surfactant
Stock solution of temper rolling liquid Active ingredients Total 34.0% by mass
Tempered rolling stock solution having the above composition.

<Liquid B4: Tempered rolling stock solution with a surfactant amount of 0.008%>
Deionized water 73.6% by mass
Aqueous rust inhibitor p-nitrobenzoic acid 9.9% by mass
1-hydroxybenzotriazole 7.6% by mass
Aqueous rust inhibitor total 17.5% by mass
Alkanolamine-based alkaline pH adjuster Isopropanolamine 8.8% by mass
(Alkaline pH adjuster 2 times mol for acid)
Surfactant Polyoxyethylene alkyl ether surfactant 0.008% by mass
Stock solution of temper rolling liquid Active ingredients Total 26.308% by mass
Tempered rolling stock solution having the above composition.

<Liquid A5: Acid and alkali pH adjuster change, tempered rolling stock solution with 2 times mol of amine to acid>
Deionized water 70.9% by mass
Aqueous rust inhibitor dodecanoic acid 6.4% by mass
Sodium benzoate 7.4% by mass
Aqueous rust inhibitor total 13.8% by mass
Alkanolamine-based alkali pH adjuster diisopropanolamine 14.7% by mass
(Alkaline pH adjuster 2 times mol for acid)
Surfactant 0.5% by mass of polyoxyethylene alkyl ether surfactant
Stock solution of temper rolling liquid Active ingredients Total 29.0% by mass
Tempered rolling stock solution having the above composition.

<Liquid A6: Acid and alkaline pH adjuster change, temper rolling stock solution with 4 times mol of amine to acid>
Deionized water 61.8% by mass
Aqueous rust inhibitor dodecanoic acid 5.6% by mass
Sodium benzoate 6.4% by mass
Aqueous rust inhibitor total 12.0% by mass
Alkanolamine-based alkaline pH adjuster diisopropanolamine 25.7% by mass
(4 times mol of alkaline pH adjuster for acid)
Surfactant 0.5% by mass of polyoxyethylene alkyl ether surfactant
Stock solution of temper rolling liquid Active ingredients Total 38.2% by mass
Tempered rolling stock solution having the above composition.

<Liquid B5: Acid and alkali pH adjuster change, acid and amine are equimolar amounts of temper rolling stock solution>
Deionized water 76.6% by mass
Aqueous rust inhibitor dodecanoic acid 7.0% by mass
Sodium benzoate 8.0% by mass
Aqueous rust inhibitor total 15.0% by mass
Alkanolamine-based alkali pH adjuster diisopropanolamine 8.0% by mass
(1 times mol of alkaline pH adjuster for acid)
Surfactant 0.5% by mass of polyoxyethylene alkyl ether surfactant
Stock solution of temper rolling liquid Active ingredients Total 23.5% by mass
Tempered rolling stock solution having the above composition.

<Liquid B6: Acid and alkali pH adjuster change, temper rolling solution stock solution with 1.5 times mol of amine to acid>
Deionized water 73.7% by mass
Aqueous rust inhibitor dodecanoic acid 6.7% by mass
Sodium benzoate 7.7% by mass
Aqueous rust inhibitor total 14.4% by mass
Alkanolamine alkali pH adjuster diisopropanolamine 11.5% by mass
(Alkaline pH adjuster for acid 1.5 times mol)
Surfactant 0.5% by mass of polyoxyethylene alkyl ether surfactant
Stock solution of temper rolling liquid Active ingredients Total 26.4% by mass
Tempered rolling stock solution having the above composition.

<Liquid B7: Acid and alkali pH adjuster change, temper rolling stock solution with 4.5 times mol of amine to acid>
Deionized water 59.9% by mass
Aqueous rust inhibitor dodecanoic acid 5.4% by mass
Sodium benzoate 6.2% by mass
Aqueous rust inhibitor total 11.6% by mass
Alkanolamine-based alkali pH adjuster diisopropanolamine 28.0% by mass
(Alkaline pH adjuster 4.5 times mol for acid)
Interfacial pressure control agent 0.5% by mass of polyoxyethylene alkyl ether surfactant
Stock solution of temper rolling liquid Active ingredients Total 40.1% by mass
Tempered rolling stock solution having the above composition.

<Liquid A7: Surfactant change, temper rolling stock solution with 2 times mol of amine to acid>
Deionized water 73.2% by mass
Aqueous rust inhibitor p-nitrobenzoic acid 9.9% by mass
1-hydroxybenzotriazole 7.6% by mass
Aqueous rust inhibitor total 17.5% by mass
Alkanolamine type
Alkaline pH adjuster Isopropanolamine 8.8% by mass
(Alkaline pH adjuster 2 times mol for acid)
Surfactant Polyoxyethylene Polyoxypropylene
Glycol block copolymer surfactant 0.5% by mass
Stock solution of temper rolling liquid Active ingredients Total 26.8% by mass
Tempered rolling stock solution having the above composition.

<Liquid B8: Surfactant change, temper rolling stock solution with equimolar amounts of acid and amine>
Deionized water 76.6% by mass
Aqueous rust inhibitor p-nitrobenzoic acid 10.3% by mass
1-hydroxybenzotriazole 8.0 mass%
Aqueous rust inhibitor total 18.3% by mass
Alkanolamine alkali pH adjuster Isopropanolamine 4.6% by mass
(1 times mol of alkaline pH adjuster for acid)
Surfactant Polyoxyethylene Polyoxypropylene
Glycol block copolymer surfactant 0.5% by mass
Stock solution of temper rolling liquid Active ingredients Total 23.4% by mass
Tempered rolling stock solution having the above composition.

<Liquid A8: Surfactant change, tempered rolling stock solution having 2 times mol of amine to acid>
Deionized water 73.2% by mass
Aqueous rust inhibitor p-nitrobenzoic acid 9.9% by mass
1-hydroxybenzotriazole 7.6% by mass
Aqueous rust inhibitor total 17.5% by mass
Alkanolamine-based alkaline pH adjuster Isopropanolamine 8.8% by mass
(Alkaline pH adjuster 2 times mol for acid)
Surfactant 0.5% by mass of polyoxyalkylene alkyl ether surfactant
Stock solution of temper rolling liquid Active ingredients Total 26.8% by mass
Tempered rolling stock solution having the above composition.

<Liquid B9: Surfactant change, temper rolling stock solution with equimolar amount of acid and amine>
Deionized water 76.6% by mass
Aqueous rust inhibitor p-nitrobenzoic acid 10.3% by mass
1-hydroxybenzotriazole 8.0 mass%
Aqueous rust inhibitor total 18.3% by mass
Alkanolamine alkali pH adjuster Isopropanolamine 4.6% by mass
(1 times mol of alkaline pH adjuster for acid)
Surfactant 0.5% by mass of polyoxyalkylene alkyl ether surfactant
Stock solution of temper rolling liquid Active ingredients Total 23.4% by mass
Tempered rolling stock solution having the above composition.

<Liquid B10> (Note: level below the lower limit of rust inhibitor mass concentration)
75.4% by weight of deionized water
Aqueous rust inhibitor dodecanoic acid 3.9% by mass
Sodium benzoate 1.7% by mass
Aqueous rust inhibitor total 5.6% by mass
Alkanolamine alkali pH adjuster diisopropanolamine 18.5% by mass
(4 times mol of alkaline pH adjuster for acid)
Surfactant Polyoxyethylene alkyl ether surfactant 0.5% by mass
Stock solution of temper rolling liquid Active ingredients Total 24.6% by mass
Tempered rolling stock solution having the above composition.

<Liquid A9>
Deionized water 73.2% by mass
Aqueous rust inhibitor p-nitrobenzoic acid 9.9% by mass
1-hydroxybenzotriazole 7.6% by mass
Aqueous rust inhibitor total 17.5% by mass
Alkanolamine-based alkaline pH adjuster Isopropanolamine 8.8% by mass
(Alkaline pH adjuster 2 times mol for acid)
Surfactant Polyoxyethylene alkyl ether surfactant 0.5% by mass
Stock solution of temper rolling liquid Active ingredients Total 26.8% by mass
Tempered rolling stock solution having the above composition. However, at the time of evaluation, the active ingredient total concentration mass% after dilution is 8%.

<Liquid B11> (Note: level exceeding the upper limit of mass concentration of rust inhibitor)
Deionized water 61.8% by mass
Aqueous rust inhibitor p-nitrobenzoic acid 9.9% by mass
1-hydroxybenzotriazole 19.0% by mass
Aqueous rust inhibitor total 28.9% by mass
Alkanolamine-based alkaline pH adjuster Isopropanolamine 8.8% by mass
(Alkaline pH adjuster 2 times mol for acid)
Surfactant Polyoxyethylene alkyl ether surfactant 0.5% by mass
Stock solution of temper rolling liquid Active ingredients Total 38.2% by mass
Tempered rolling stock solution having the above composition. However, the total mass concentration% of active ingredients after dilution is 8% at the time of evaluation.

<Liquid A10>
Deionized water 61.8% by mass
Aqueous rust inhibitor dodecanoic acid 5.6% by mass
Sodium benzoate 6.4% by mass
Aqueous rust inhibitor total 12.0% by mass
Alkanolamine-based alkaline pH adjuster diisopropanolamine 25.7% by mass
(4 times mol of alkaline pH adjuster for acid)
Surfactant Polyoxyethylene alkyl ether surfactant 0.5% by mass
Stock solution of temper rolling liquid Active ingredients Total 38.2% by mass
Tempered rolling stock solution having the above composition. However, at the time of evaluation, the active ingredient total concentration mass% after dilution is 8%.

<Liquid B12> (Note: A level exceeding the upper limit of the amine component mass concentration that is a pH adjuster)
Deionized water 58.0% by mass
Aqueous rust inhibitor dodecanoic acid 5.3% by mass
Sodium benzoate 6.0% by mass
Aqueous rust inhibitor total 11.3% by mass
Alkanolamine-based alkali pH adjuster diisopropanolamine 30.2% by mass
(Alkaline pH adjuster 5 times mol for acid)
Surfactant Polyoxyethylene alkyl ether surfactant 0.5% by mass
Stock solution of temper rolling liquid Active ingredients Total 42.00% by mass
Tempered rolling stock solution having the above composition. However, at the time of evaluation, the active ingredient total concentration mass% after dilution is 8%.

[1] Cold-rolled steel sheet Aluminum killed steel having a thickness of 0.8 mm is pickled with 3% hydrochloric acid at 70 ° C. for 30 seconds, then washed with water, and then nickel plating hexahydrate 15 g / l Ni plating bath ( Ni plating was performed at a current density of 5 A / dm 2 at a plating bath temperature of 40 ° C. The amount of Ni adhesion was controlled by changing the energization time.

[2] Temper rolling (1) Temper rolling with a small rolling mill Using the liquids A1 to 10 and the liquids B1 to B12 as a stock solution of the temper rolling liquid, the active ingredients in the rolling are each mass% in Table 1. Thus, it was diluted with deionized water and temper-rolled by a small rolling mill equipped with a dull roll (surface roughness Ra = 3 μm, diameter 150 mm). The rolling conditions were a rolling speed of 10 m / min and a reduction rate of 1%. The amount of residual organic matter on the surface of the steel sheet was adjusted by adjusting the flow rate of draining air on the exit side of the small rolling mill.

(2) Measurement of amount of residual organic matter in temper rolling liquid remaining on steel sheet surface after rolling Prepare a cut sheet sample with a size of 100 mm x 100 mm from the temper rolled steel sheet and immerse it in 1000 cc of ethanol for 30 minutes. After extracting the remaining organic matter amount, the extract was concentrated to 5 ml with an evaporator and subjected to liquid chromatography analysis. The amount of residual organic matter per side was calculated by the weight of the residual organic matter extracted (mg) / half the cut plate sample area (m ² ).

[3] Application of rust-preventive oil after temper rolling A rust-preventive oil (Parker Kosan Knoxlast 530F40) was applied to the temper-rolled sample using a lab roll coater (urethane rubber roll, diameter 150 mm). The amount of oil coating was almost constant in the range of 1.0 to 1.5 g / m ² . The amount of oil was controlled by the number of roll rotations and roll rolling force.

[4] Performance Evaluation The following performance evaluation was performed on the steel plate samples prepared under the various conditions. Table 1 summarizes sample levels and performance evaluation results.

(1) Degreasing evaluation Degreasing was evaluated by the surface water wetted area ratio when washed with water after alkaline degreasing and taken out after washing with water. As the alkaline degreasing solution, 20 g / L of FC-4460A manufactured by Nippon Parkerizing Co., Ltd. and 12 g / L of FC-4460B dissolved in 40 ° C. aqueous solution (pH 12.1) were used. The main components are sodium carbonate, phosphate, sodium hydroxide, and a surfactant. Considering process fluctuations such as liquid deterioration and pH change due to contamination of degreased rust preventive oil during continuous operation in the consumer, evaluation with the new liquid is insufficient, so 20 g of Nippon Parkerizing FC-4460 / L Dissolved alkaline degreasing solution at 40 ° C. In advance, 10 g / L of rust-preventing oil (Parker Kosan Knoxlast 530F) was added in advance, and after sufficient stirring, carbon dioxide was included to reduce the pH to 10. 20 L of liquid was prepared. The simulated deterioration solution was placed in a stainless steel container, and the steel plate sample was immersed for 2 minutes in a state of stirring at 500 rpm using a 10 mmφ blade-type stirring blade, and alkali degreasing was performed. After degreasing, spray water washing was performed for 60 seconds, and the water wetted area ratio on the steel sheet surface 30 seconds after the water washing was visually evaluated. Evaluation was according to the following criteria.

Score ◎: 95-100% wet
○: Water wet 80-94%
Δ: 50-79% wet
X: Less than 50% wet

(2) Chemical conversion treatment evaluation The steel sheet sample after degreasing and water washing was sprayed with a surface conditioner (preparene 4040 made by Nihon Parkerizing, temperature 23 ° C.) for 20 seconds, and a chemical treatment solution (Palbond 3020 made by Nihon Parkerizing, phosphoric acid). A chemical conversion film was formed by immersing in a zinc chemical conversion treatment agent at a temperature of 42 ° C. for 2 minutes, followed by spray water washing for 30 seconds and drying. About the sample which performed the chemical conversion treatment, the visual evaluation of the external appearance, SEM observation of the chemical conversion crystal form was performed, and the chemical conversion treatment film adhesion amount was measured. SEM observation was performed at an acceleration voltage of 20 kV and a magnification of 3000 times. The quality as a chemical conversion film was judged comprehensively from the crystal form and size of visual appearance observation and SEM observation. Moreover, the amount of chemical conversion film was measured by the weight method from the weight difference before and after chemical film peeling. The chemical conversion film was peeled off by immersing the steel sheet in a 5 wt% chromic anhydride aqueous solution at 70 ° C. for 15 minutes. The 5 wt% chromic anhydride aqueous solution was prepared by adding chromic anhydride (Wako Standard Grade 1 product) manufactured by Wako Pure Chemical Industries to ion-exchanged water.

(3) Rust prevention test (3-1) Indoor exposure test Rust on the surface of a 100 x 100 mm steel plate coated with antirust oil, standing on a sample stand one by one in a sample storage warehouse for 14 days The occurrence of discoloration was visually evaluated. Evaluation was according to the following criteria.

Rating ◎: No rust or discoloration ○: Less than 3% rust or discoloration △: 3 to 30% rust or discoloration
×: Rust and discoloration occurred over 30%

(3-2) Stack Rust Prevention Test A set of five 100 × 100 mm steel plate samples coated with rust preventive oil was taken as one set, and the stacked steel plate samples were sandwiched between Teflon (registered trademark) sheets, and then the end 4 Sandwiched between 150 x 150 x 4 mm thick stainless steel plate with bolt holes at the location, bolted with a torque of 2 Nm, left in a constant temperature and humidity test device of 50 ° C x 95% humidity for 14 days, then taken out and stacked The surface of the test sample was visually observed. Evaluation was according to the following criteria.

Rating ◎: No rust or discoloration ○: Less than 3% rust or discoloration △: 3 to 30% rust or discoloration
×: Rust and discoloration occurred over 30%

(4) Build-up resistance test Rubber roll squeezing is performed on a steel plate sample (without rust-prevention oil coating, 100 × 100 mm size) immediately after temper rolling. After squeezing 100 samples, the roll surface is dried with hot air of 50 ° C. while rotating the roll, and the state of occurrence of deposits on the roll surface is visually confirmed. Evaluation was according to the following criteria.

Grade ◎: No deposit ○: Very little deposit is observed on part of roll △: Very little deposit is observed on the entire roll surface ×: Deposit is observed on the entire roll surface

(5) Gum-up resistance test 10 ml of temper rolling solution and 20 ml of rust preventive oil (Parker Kosan Knoxlast 530F40) were uniformly mixed and dried at 100 ° C. for 1 hour to evaporate the water. 2 roll type, urethane rubber roll, diameter 150 mm, rotation speed 50 rpm) is dropped onto a roll part, and the surface condition of the roll after rotating continuously for 72 hours is visually confirmed. The pick-up roll and applicator roll were rotated in a natural manner, and the roll was rotated in contact. Evaluation was according to the following criteria.

Rating ◎: There is no deposit and the liquid is evenly distributed ○: Stickiness of the liquid is slightly observed, but there is no deposit △: Stickiness of the liquid is observed, or a slight amount of deposit is observed on a part of the roll ×: Deposits are observed on the entire roll surface

  Table 1 shows the results of evaluation under the above conditions. Those satisfying all the requirements of the present invention were good in all of degreasing properties, evaluation of chemical conversion films, indoor exposure rust prevention properties, stack rust prevention properties, build-up resistances, and gum-up resistances.

Claims (5)

When temper rolling a Ni-plated steel sheet,
Water-soluble rust preventive agent by mass: 1 to 6%
Alkanolamine-based alkaline pH adjuster: 0.8 to 5.5%,
Surfactant: 0.005 to 1%,
The remainder consists of water and inevitable impurities, and the total amount of the water-soluble rust inhibitor, alkanolamine-based alkali pH adjuster, and surfactant is 3 to 8% by mass, and the acid contained in the water-soluble rust inhibitor is 1 mol. A temper rolling method for a Ni-plated steel sheet excellent in degreasing properties, characterized by using a temper rolling solution containing an alkanolamine-based alkaline pH adjuster in an amount of 2 to 4 mol.   The temper rolling of a Ni-plated steel sheet excellent in degreasing properties according to claim 1, wherein the alkanolamine-based alkaline pH adjuster is one or a mixture of two of monoisopropanolamine and diisopropanolamine. Method.   The water-soluble rust preventive agent is one or a mixture of two or more of benzoic acid derivatives, organic carboxylic acids, and organic chelate nitrogen-containing compounds. A method for temper rolling of a steel sheet plated with Ni.   The method for temper rolling a Ni-plated steel sheet having excellent degreasing properties according to any one of claims 1 to 3, wherein the surfactant is a nonionic surfactant.   The temper rolling liquid according to any one of claims 1 to 4, wherein the total content of the water-soluble rust preventive agent, the alkanolamine-based alkali pH adjuster, and the surfactant is 5 to 50% by mass, the rest being water and A method for temper rolling of a Ni-plated steel sheet having excellent degreasing characteristics, obtained by diluting a stock solution for temper rolling liquid, which is an inevitable impurity, with water, and using this temper rolling liquid .

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