JP2017043090A - Polyethylene coated steel tube and manufacturing method therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a polyethylene coated steel tube excellent in cathode peeling resistance of a polyethylene coated layer and capable of being manufactured without conducting a chromate treatment.SOLUTION: There is provided a polyethylene coated steel tube having a polyethylene coated layer on a steel pipe outside surface with the amount of duct contained in the steel tube outside surface and the polyethylene coated layer having surface element percentage of Fe by measuring a surface contacting with the steel tube outside surface of peeled polyethylene coated layer by XPS of 1.0% or less.SELECTED DRAWING: None

Description

  The present invention relates to a polyethylene-coated steel pipe excellent in adhesion of a polyethylene coating layer and a method for producing the same. The present invention also relates to an outer polyethylene-coated steel pipe used for gas pipes, water pipes, cable protection pipes, line pipes and the like.

  A polyethylene-coated steel pipe having a steel pipe surface coated with a polyethylene coating layer as an anticorrosion layer has excellent anticorrosion properties and is used for various pipes. Polyethylene-coated steel pipes are increasingly used for embedment in the seabed and underground, and in that case, anticorrosion is often used in combination. Although the steel pipe of the polyethylene-coated steel pipe is anticorrosive due to the effect of cathodic protection, there is a problem that the polyethylene coating layer tends to peel from the outer surface of the steel pipe, and this problem is known as cathodic peeling.

  It is known that chromate treatment is effective as a method for suppressing such cathode peeling. For example, Patent Document 1 discloses a resin-coated heavy-duty anticorrosive steel material that is a chromate-coated steel material having a chromate layer on the surface of the steel material, in which an epoxy primer layer, a maleic anhydride-modified polyolefin layer, and a polyolefin layer are sequentially laminated. Patent Document 2 discloses that a specific epoxy primer is applied to the surface of a steel material and that chromate treatment is performed as a base treatment.

  In recent years, there has been a demand for an organic coated steel material excellent in corrosion resistance that is not subjected to chromate treatment, that is, subjected to non-chromate treatment, from the viewpoint of environmental load. Patent Document 3 discloses an organic coated steel sheet that is non-chromated and has excellent corrosion resistance.

JP-A-2005-35061 JP 2000-190422 A JP 2011-111638 A

  In the methods of Patent Documents 1 and 2, there is a problem that a chromate treatment with a high environmental load is required when coating a steel pipe. The method of Patent Document 3 has a problem that the plated steel sheet is treated to improve the corrosion resistance and does not suppress the cathode peeling.

  Accordingly, an object of the present invention is to provide a polyethylene-coated steel pipe that solves the problems of the prior art as described above, is excellent in the cathode peel resistance of the polyethylene coating layer, and can be manufactured without performing chromate treatment. is there.

  The inventors of the present invention have made extensive studies to solve the above-mentioned problems, and have found that the amount of dust existing between the outer surface of the steel pipe and the polyethylene coating layer affects the cathode peeling. Thus, a plurality of dust-coated polyethylene-coated steel pipes on the outer surface of the steel pipe were manufactured, and the relationship with the cathode peeling resistance was examined to complete the present invention.

  The gist of the present invention is as follows.

  [1] A polyethylene coated steel pipe having a polyethylene coating layer on the outer surface of the steel pipe, wherein the amount of dust contained between the outer surface of the steel pipe and the polyethylene coating layer is in contact with the outer surface of the peeled polyethylene coating layer. A polyethylene-coated steel pipe in which the Fe surface element ratio measured by XPS is 1.0% or less.

  [2] The polyethylene-coated steel pipe according to [1], which is used together with cathodic protection.

  [3] The polyethylene-coated steel pipe according to [1] or [2], which is for embedding in the seabed or underground.

  [4] After the blast treatment, dust on the outer surface of the steel pipe is adhered to the adhesive medium by the method specified in JIS Z0313 (2004), the adhesive medium is pasted on white paper, and the brightness at 256 gradations is determined by image analysis. A method for producing a polyethylene-coated steel pipe, in which a steel pipe having an average value of 220 or more is coated with polyethylene.

  [5] The polyethylene-coated steel pipe according to [4], wherein the outer surface of the steel pipe having an average value of 220 or more is coated with a silane coupling agent and dried, and then coated with polyethylene. Production method.

  [6] The method for producing a polyethylene-coated steel pipe according to [5], wherein the silane coupling agent is dried by any one of infrared heating, induction heating, hot air heating, or a combination thereof.

  [7] The method for producing a polyethylene-coated steel pipe according to [6], wherein the silane coupling agent is dried by infrared heating.

  In the present invention, the excellent adhesion of the polyethylene coating layer means that the average value of the cathode peeling distance is 20 mm or less in the test described in the examples described later.

  In the polyethylene-coated steel pipe of the present invention, when the anticorrosion is used in combination, the cathode peeling of the polyethylene coating layer is effectively suppressed, and excellent anticorrosion properties are exhibited. Thus, since the polyethylene-coated steel pipe of the present invention has excellent cathode peeling resistance, it is particularly suitable for embedding in the seabed or underground.

  The configuration of the present invention will be described below. Since the polyethylene-coated steel pipe of the present invention exhibits excellent cathode peeling resistance, it is necessary to define the amount of dust on the outer surface of the steel pipe. The dust is mainly composed of Fe, and usually contains blast-treated particles, steel pipe fragments peeled off by blasting, and scales remaining on the outer surface of the steel pipe.

1. Cathodic delamination occurs between the outer surface of the steel pipe and the polyethylene-coated layer with respect to the amount of dust adhering to the outer surface of the steel pipe. If a large amount of dust adhered by blasting or the like adheres to the outer surface of the steel pipe, the outer surface of the steel pipe and the polyethylene coating layer are not sufficiently adhered to each other, so that the cathode is easily peeled off. Therefore, excellent cathode peeling resistance is exhibited by controlling the amount of dust adhering to the outer surface of the steel pipe as follows.

  For example, the polyethylene coating layer of a polyethylene coated steel pipe is forcibly peeled, and the surface of the peeled coating layer that is in contact with the outer surface of the steel pipe is analyzed by XPS (X-ray photoelectron spectroscopy). It shall be as follows. As described in the manufacturing method described later, the amount of dust attached to the outer surface of the steel pipe can be reduced by, for example, air blowing on the outer surface of the steel pipe. The method for forcibly peeling the polyethylene coating layer is not particularly limited. For example, a part of a polyethylene-coated steel pipe having a size of about 20 mm × 50 mm is cut out and used as a measurement piece, and the measurement piece is immersed in liquid nitrogen and taken out. When the polyethylene coating layer is hit with a plastic hammer, the polyethylene coating layer is peeled off from the outer surface of the steel pipe. The 10 mm × 10 mm surface of the peeled polyethylene coating layer in contact with the outer surface of the steel pipe is analyzed by XPS under the following conditions. By making the surface element ratio of Fe 1.0% or less, the adhesion between the polyethylene coating layer and the outer surface of the steel pipe is improved, and the cathode peeling is less likely to occur. When the surface element ratio of Fe exceeds 1.0%, the adhesion between the polyethylene coating layer and the outer surface of the steel pipe is lowered, and the cathode peeling tends to occur. The surface element ratio of Fe is preferably 0.5% or less, more preferably 0.3% or less.

-XPS analysis conditions-
(1) The XPS analysis conditions are such that the photoelectron escape angle is 45 degrees, the measurement range is about 5 mm × 5 mm, and the photoelectron energy is scanned in the range of 0 to 1100 eV to obtain the existing element information. (2) The ratio of Fe element can be obtained from the ratio of the peak intensity of Fe to the total peak intensity of all elements obtained.

2. There are no particular restrictions on the type and dimensions of the base steel pipe used in the present invention for the steel pipe, and examples of the type of steel pipe include an electric-welded steel pipe, a spiral steel pipe, a UOE steel pipe, and a press-bend steel pipe. It is not limited. The base steel pipe is preferably an electric resistance steel pipe from the viewpoint of strength and economy.

3. Regarding the polyethylene coating, common materials can be used for the polyethylene coating. The polyethylene coating layer can be produced by forming a primer layer, an adhesive polyethylene layer, and a polyethylene layer in this order from the side in contact with the outer surface of the steel pipe. The polyethylene coating layer may further include a surface treatment layer formed using a silane coupling agent described later. The polyethylene coating layer of the present invention does not include a surface treatment layer formed by chromate treatment.

  As a primer for forming the primer layer, for example, an epoxy primer (JIS G3477-1: 2012) can be used.

  Examples of the adhesive polyethylene resin for forming the adhesive polyethylene layer include maleic anhydride-modified polyethylene and unsaturated carboxylic acid-modified polyethylene.

As the polyethylene resin for forming the polyethylene layer, any of low density, medium density, and high density may be used, and in particular, high density polyethylene resin (0.94 to 0.97 g / cm ³ ) is a viewpoint of corrosion resistance. Is desirable. If necessary, additives such as antioxidants, ultraviolet absorbers, flame retardants, pigments, fillers, lubricants, antistatic agents, and colorants can be added to the polyethylene resin.

  The polyethylene coating layer preferably has a thickness of about 1 mm to 5 mm from the viewpoint of corrosion resistance and economy. From the standpoint of corrosion resistance, a more preferred lower limit is 2.5 mm.

4). About a manufacturing method The manufacturing method of the polyethylene covering steel pipe of this invention is demonstrated below. First, the outer surface of the steel pipe is blasted. Thereafter, dust on the outer surface of the steel pipe is removed by air blow or the like. Next, the dust on the outer surface of the steel pipe after air blowing is attached to the cellophane adhesive tape (JIS Z1522: 2009), which is an adhesive medium, by the method specified in JIS Z0313 (2004), and the adhesive medium is attached to white paper, and the image By analysis, luminance at 256 gradations is measured, and it is confirmed that the average value is 220 or more. Further, the dust removal status may be confirmed by comparing with a sample sample that has been confirmed to have a luminance of 220 or more in advance. The adhesive medium is a transparent thin film having an adhesive layer having an adhesive strength of 1.8 N / 10 mm or more.

  The white paper has a whiteness of 90% to 95% (also referred to as white plain paper in the examples described later). Usable white paper includes, for example, PPC paper and inkjet paper shown in JIS P0001: 1998.

  The luminance is measured with 256 gradations. More specifically, the brightness is measured by, for example, scanning a cellophane adhesive tape affixed on white paper using a multifunction machine or the like, and using Adobe image analysis software Photoshop CS6 to locate an arbitrary position of the cellophane adhesive tape image. The average value of the range luminance can be measured.

  The size of the image analysis is not particularly limited, but is preferably 20 mm × 20 mm from the viewpoint of simplicity. Further, in obtaining the average value of luminance, the number of measurements is 2 or more. The number of measurements is preferably 2-5.

  When the amount of dust attached is large, the average value of luminance is low. When polyethylene coating is performed in a state where the average value of luminance is 220 or less and the amount of dust is small, the adhesion between the outer surface of the steel pipe and the polyethylene coating layer is improved, and the cathode peeling hardly occurs. When the average value of the luminance is less than 220, the adhesion between the polyethylene coating layer and the outer surface of the steel pipe is lowered, and cathode peeling is likely to occur. The average value of luminance is preferably 230 or more, and more preferably 240 or more.

  The method for forming the polyethylene coating layer is not particularly limited. For example, an epoxy primer is applied to a steel pipe from which dust on the outer surface has been removed, heated to a predetermined temperature (for example, 130 to 170 ° C.) with an induction heating device, a hot air furnace, etc., and an adhesive polyethylene layer having polarity on the outside There is a method in which a polyethylene layer is sequentially extruded from a round die, a T die, or the like, and a coating layer is formed, followed by cooling. In addition, there may be mentioned a method in which an epoxy primer is applied to a steel pipe from which dust on the outer surface has been removed, and after heating, the adhesive polyethylene layer and the polyethylene layer are simultaneously extruded and coated with a round die, a T die or the like. In this case, two coating layers are formed at a time. In particular, in this case, the adhesiveness of the polyethylene coating layer after forming the polyethylene-coated steel pipe is excellent. The polyethylene coating layer preferably has a thickness of about 1 mm to 5 mm from the viewpoint of corrosion resistance and economy. From the standpoint of corrosion resistance, a more preferred lower limit is 2.5 mm.

  Furthermore, in order to improve the cathode peel resistance, a silane coupling agent diluted to about 0.5 to 2% by mass is sprayed after the steel tube is heated and before the resin for forming the polyethylene coating layer is coated. May be applied and dried to form a surface treatment layer. Although a silane coupling agent is not specifically limited, What has functional groups, such as an epoxy group, a mercapto group, and an amino group, can be used. Examples of the silane coupling agent having an epoxy group include 3-glycidoxypropyltrimethoxysilane, 3-glycidoxypropylmethyldiethoxysilane, 3-glycidoxypropyltriethoxysilane, and 3-glycidoxypropyl. Examples include methyldimethoxysilane. Examples of the silane coupling agent having a mercapto group include 3-mercaptopropylmethyldimethoxysilane and 3-mercaptopropyltrimethoxysilane. Examples of the silane coupling agent having an amino group include 3-aminopropyltrimethoxysilane and 3-aminopropyltriethoxysilane. The drying conditions for the silane coupling agent can be selected as appropriate.

For drying the silane coupling agent, infrared heating, induction heating, hot air heating, or a combination thereof can be used. When the silane coupling agent is dried by heating, moisture is removed and a condensation reaction with a hydroxyl group on the steel surface and the like improves the resistance to cathodic peeling.
When the silane coupling agent is dried by infrared heating, the resistance to cathodic stripping is improved compared to the case where other heating methods are employed. Therefore, it is advantageous to perform infrared heating for applications that require better cathode peel resistance.

  As described above, it is preferable that the polyethylene-coated steel pipe of the present invention is used together with an anticorrosion. Moreover, the polyethylene-coated steel pipe of the present invention is suitable for use in the seabed or underground. It is more preferable that the polyethylene-coated steel pipe of the present invention is embedded in the seabed or underground and used together with cathodic protection.

  Examples of the present invention will be described below. In this example, the number of dust deposits on the outer surface of the steel pipe is different by the following method. 1-15 polyethylene coated steel tubes were tested. The technical scope of the present invention is not limited to the following examples.

(Brightness measurement)
Dust on the outer surface of the blasted JIS SGP 400A steel pipe is removed by air blow, and the dust on the outer surface of the steel pipe is applied to the cellophane adhesive tape (size: 24 mm x 200 mm) by the method specified in JIS JIS Z0313 (2004). The cellophane adhesive tape was attached to white plain paper. The tape affixed to the white plain paper was then converted into electronic data by a scanner, and the brightness of the cellophane adhesive tape was determined by the above-described method using image analysis software (Photoshop CS6 manufactured by Adobe). In addition, the brightness | luminance was measured 3 times per steel pipe, and the average value was calculated | required.

(Polyethylene coating)
A commercially available liquid epoxy resin (“Basic Liquid Type 828” manufactured by Mitsubishi Chemical Corporation) and a curing agent (“Modified Aliphatic Amine Grade T” manufactured by Mitsubishi Chemical Corporation) were mixed on the outer surface of the steel pipe subjected to the air blow treatment. The epoxy primer was applied by spraying so as to have a film thickness of 40 μm, and was cured by induction heating to a surface temperature of 150 ° C.

  Thereafter, a commercially available adhesive polyethylene resin (“Admer NE065” manufactured by Mitsui Chemicals, Inc.), a polyethylene resin (“HI-ZEX5100E” manufactured by Prime Polymer Co., Ltd., which is a high density polyethylene resin) is coated by extrusion coating. A polyethylene-coated steel pipe having a polyethylene coating layer thickness of 3 mm was produced.

(Surface treatment layer formation)
In addition, for some steel pipes, 3-glycidoxypropyltrimethoxysilane having an epoxy group (“KBM-403” manufactured by Shin-Etsu Chemical Co., Ltd.) having an epoxy group is used as a silane coupling agent for the above-described air blow-treated steel pipe. A treatment liquid diluted with pure water so that the silane coupling agent is 1% by mass is applied by spraying, and then heated so that the treatment liquid is completely dried by each apparatus of infrared heating, induction heating, and hot air heating, After forming the surface treatment layer, the above polyethylene coating was performed. Those having a surface treatment layer are described as “epoxysilane” in the “surface treatment liquid” column in Table 1.

(XPS measurement)
After the polyethylene coating, the end 20 mm × 50 mm of the steel pipe was cut out and used as a measurement piece. After the measurement piece was immersed in liquid nitrogen, it was taken out and hit with a plastic hammer to peel off the polyethylene coating layer from the outer surface of the steel pipe. XPS measurement was performed on the outer surface side 10 mm × 10 mm of the peeled polyethylene coating layer by the above-described method, and the surface element ratio of Fe was measured.

(Reference example: No. 15)
As a reference example, a polyethylene-coated steel pipe using a steel pipe treated with chromate was prepared. Instead of the above silane coupling agent, a chromate treatment solution (“Cosmer 100” manufactured by Kansai Paint Co., Ltd.) diluted with pure water to 1/5 (mass%) is used, and Cr is converted to the outer surface of the steel pipe. The chromate layer was formed by spray-coating so that the adhesion amount was 300 mg / m ² and heating and drying so that the steel tube surface temperature reached 100 ° C. Other than that was carried out similarly to the other Example, and produced the polyethylene covering steel pipe. The amount of Cr equivalent deposited is 1 m based on the measurement of the amount of Cr in the stripping solution by absorptiometry after a dummy plate with a chromate layer is prepared and the chromate film of a predetermined area is stripped with 10% NaOH. ^The amount of Cr equivalent adhesion per ² was calculated.

(Cathode peeling test)
A test piece of an appropriate size was taken from the polyethylene-coated steel tube, and the cathode peeling distance was measured by the following method to evaluate the cathode peeling resistance. A circular artificial defect having a diameter of 6 mmφ was formed at the center of the test piece, and the outer surface of the steel pipe was exposed. An acrylic cylinder having a diameter of 70 mmφ centered on the artificial defect portion was vertically installed on the polyethylene coating layer, fixed to the polyethylene coating layer with a sealing material, and the inside of the cylinder was filled with a 3% by mass NaCl aqueous solution to form a cell. .

  Platinum was used as the counter electrode, and the potential of the steel pipe at the artificial defect portion was maintained at -1.5 V vs SCE using a potentiostat. The test piece was left still in a constant temperature bath at 60 ° C., and the potential was maintained for 28 days.

  As a result of the above test, cathode peeling occurred on the test piece. Next, after collecting the test piece, the cell was removed, and the periphery of the artificial defect portion was forcibly separated using a chisel and a cutter. At the periphery of the artificial defect portion, the polyethylene coating layer was peeled off from the outer surface of the steel pipe, and the surface of the steel pipe was exposed. Measure the distance of the peeling part of the polyethylene coating layer from the edge of the artificial defect part in 4 directions centered on the artificial defect part (12 o'clock, 3 o'clock, 6 o'clock, 9 o'clock direction with the tube axis direction being 12 o'clock) The average value was defined as the cathode separation distance (mm). The smaller the value of the cathode peeling distance, the better, and “20 mm or less” was considered acceptable. The accepted polyethylene-coated steel pipe is suitable for embedment in the seabed or underground. Table 1 shows the test results.

  Invention Example No. In Nos. 1 to 10, the cathode peeling distance satisfies the target of 20 mm or less, and exhibits excellent cathode peeling resistance. In all of the inventive examples in which the treatment liquid having a silane coupling agent was dried by infrared heating, the cathode peeling distance was less than 11.5 mm, and excellent cathode peeling resistance was accurately realized.

  No. 11 to 14 are comparative examples. No. Nos. 11 and 12 have a large amount of dust on the outer surface of the steel pipe, the XPS measurement result exceeds 1.0%, the average value of luminance is less than 220, and the cathode peeling distance does not satisfy the target value. No. 13 and 14 used a silane coupling agent as the surface treatment, but the amount of dust on the outer surface of the steel pipe was large, the XPS measurement result exceeded 1.0%, the average value of luminance was less than 220, and the cathode peeling distance was The target value is not satisfied.

  No. Reference numeral 15 denotes a chromate treatment material of a reference example. The chromate treatment material has a large amount of dust on the outer surface of the steel pipe, and the XPS measurement result exceeds 1.0%, but the cathode separation distance satisfies the target value. However, it is not desirable because the environmental load is high.

Claims (7)

  The surface of the polyethylene coated steel pipe having a polyethylene coating layer on the outer surface of the steel pipe, the amount of dust contained between the outer surface of the steel pipe and the polyethylene coating layer being in contact with the outer surface of the steel pipe of the peeled polyethylene coating layer is measured by XPS. A polyethylene-coated steel pipe in which the surface element ratio of Fe is 1.0% or less.   The polyethylene-coated steel pipe according to claim 1, which is used together with an anticorrosion.   The polyethylene-coated steel pipe according to claim 1 or 2, which is used for embedding in the seabed or underground.   After blasting, dust on the outer surface of the steel pipe is adhered to the adhesive medium by the method specified in JIS Z0313 (2004), the adhesive medium is attached to white paper, and the luminance at 256 gradations is measured by image analysis. A method for producing a polyethylene-coated steel pipe, in which a steel pipe having an average value of 220 or more is coated with polyethylene.   5. The method for producing a polyethylene-coated steel pipe according to claim 4, wherein the outer surface of the steel pipe having an average luminance value of 220 or more is coated with a silane coupling agent and dried, and then is coated with the polyethylene.   The method for producing a polyethylene-coated steel pipe according to claim 5, wherein the silane coupling agent is dried by infrared heating, induction heating, hot air heating, or a combination thereof.   The method for producing a polyethylene-coated steel pipe according to claim 6, wherein the silane coupling agent is dried by infrared heating.