JP2003301300A - Horizontal degreasing apparatus and vertical degreasing apparatus for steel band - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide horizontal and vertical degreasing apparatuses for a steel band which can prevent the deposition of an oil on a steel band after electrolytic degreasing and the occurrence of press flaws and can keep the surface of the steel band in a good degreased state. <P>SOLUTION: The horizontal degreasing apparatus 10 is equipped with an electrolytic degreasing means 15 having electrodes 13, 14 for removing an oil attached to the surface of a steel band 11 in a cleaning liquid 12 and a mechanical degreasing means 19 for removing the oil attached to the surface of the steel band 11 with brush rolls 17, 18. At the downstream side of the electrode 14, a pair of fluid nozzles 16 for blowing a fluid are installed so as to face to each other across the steel band 11. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a degreasing device for removing oil adhered to the surface of a steel strip.

[0002]

2. Description of the Related Art When a steel strip is subjected to a surface treatment such as plating or painting, it is necessary to remove (degrease) oil adhering to the surface of the steel strip. Here, the degreasing process of the oil adhered to the surface of the steel strip, for example, the electrolytic degreasing process of degreasing by passing the steel strip through the electrolytic degreasing tank storing the cleaning liquid, and the steel strip after electrolytic degreasing There is a mechanical degreasing process of removing oil by passing between the brush rolls and a water spray (rinsing) process of spraying water on the steel strip after the mechanical degreasing to wash away the cleaning liquid. Therefore, for example, the horizontal degreasing device 80 as shown in FIG. 3 was used to degrease the steel strip 81.

In FIG. 3, the conveyed steel strip 81 is first introduced into a electrolytic degreasing tank 83 storing a cleaning liquid 82 through a seal roll 84 for electrolytic degreasing. In the electrolytic degreasing tank 83, for example, two pairs of electrodes 85 facing each other with a gap are provided, and the steel strip 81 is conveyed through the gap between the electrodes 85, and a ringer for suppressing the sagging of the steel strip 81. It is led out from the electrolytic degreasing tank 83 via a roll 86. A voltage is applied between the electrodes 85, and when the steel strip 81 passes between the electrodes 85, a current flows between one side of the electrode 85 and one surface of the steel strip 81 facing the one side. Then, the cleaning liquid 82 is electrolyzed. At this time, different kinds of gas (oxygen gas on the anode side and hydrogen gas on the cathode side) are generated on one surface of the steel strip 81 facing the one side of the electrode 85. By the generation of this gas,
The oil content adhering to one surface of the steel strip 81 was floated up. At the same time, a current also flows between the other side of the electrode 85 and the other side surface of the steel strip 81 facing the other side to electrolyze the cleaning liquid 82, and the steel strip facing the other side of the electrode 85. Different kinds of gas were generated on the other surface of the steel strip 81, and the oil adhered to the other surface of the steel strip 81 was floated by the generation of this gas. Steel strip 81 led out from the electrolytic degreasing tank 83 via a Ringer roll 86
Is introduced into the mechanical degreasing tank 89 in which the cleaning liquid 88 is stored, via the seal roll 87. In the mechanical degreasing tank 89, for example, two pairs of brush rolls 90 are provided. When the steel strip 81 passes between the brush rolls 90, it floats on the surface of the steel strip 82 in the electrolytic degreasing process. The oil is efficiently scraped off and removed by the brush roll 90. The steel strip 81 that has passed through the brush roll 90 is led out from the mechanical degreasing tank 89 via the seal roll 91,
It is transported to a water spray (rinse) process (not shown).

Here, when electrolytic degreasing is performed at a low current density, it is necessary to lengthen the electrode 85 in order to secure a predetermined amount of Coulomb, and the sag of the steel strip 81 becomes large and the steel strip 81 is conveyed. Causes a problem. Further, the installation area of the electrolytic degreasing tank 83 becomes large, which causes a problem in installation.
Therefore, as shown in FIG. 4, a vertical degreasing device 93 is used which can make the volume of the electrolytic degreasing tank 92 compact even when performing electrolytic degreasing at a low current density. In FIG. 4, the steel strip 81 is introduced from above into an electrolytic degreasing tank 92 in which the conveying direction is changed via a deflector roll 94 to perform electrolytic degreasing. In the electrolytic degreasing tank 92, the sink roll 9 is provided on the lower side.
5, a pair of electrodes 9 before and after the sink roll 95
6, 97 are provided. The steel strip 81 has electrodes 96, 9
7 is conveyed through each gap. Similar to the case of the horizontal degreasing device 80, when the steel strip 81 passes between the electrodes 96 and 97, the steel strip 81 is formed by the gas generated by the electrolysis of the cleaning liquid 82.
The oil that adheres to both sides of the floats.

The steel strip 81 that has passed through the electrode 96 is transported upward through the sink roll 95 with its transport direction reversed, and passes through the gap between the electrodes 97. At this time, the cleaning liquid 82 existing between the electrode 97 and the steel strip 81 is electrolyzed, and the generated gas lifts the oil component attached to both surfaces of the steel strip 81. As a result, the steel strip 81 comes out of the electrode 97 in a state where the cleaning liquid 82 containing floating oil is present on the surface. Next, the steel strip 81 is introduced into the mechanical degreasing tank 89 with the conveying direction changed by the hold down rolls 98, and mechanical degreasing substantially the same as that of the horizontal degreasing device 80 is performed.

[0006]

In the horizontal degreasing device 80 shown in FIG. 3, the cleaning liquid 82 is conveyed while being sandwiched by ringer rolls 86 in order to prevent the cleaning liquid 82 from flowing out of the electrolytic degreasing tank 83. Therefore, the oil floating on the surface of the steel strip 81 due to the electrolytic degreasing is pressed by the ringer roll 86 when passing through the ringer roll 86 and adheres to the surface of the steel strip 81 again, which reduces the degreasing effect. Is occurring. Further, the steel strip 81 that has been electrolytically degreased is the ringer roll 8
When passing through 6, oil adheres to the surface of the Ringer roll 86. Then, as the electrolytic degreasing is continuously performed, the amount of oil attached to the surface of the Ringer roll 86 increases and solidifies. For this reason, the oil component adhering to the surface of the ringer roll 86 reattaches to the surface of the steel strip 81 and stains the surface, and the oil component solidified on the surface of the ringer roll 86 causes dents on the surface of the steel strip 81. There is a problem.

Further, in the vertical degreasing device 93 shown in FIG.
The steel strip 81 after the electrolytic degreasing is changed in the conveying direction by the hold down rolls 98, and is sent to a mechanical degreasing step in which mechanical degreasing is performed. Therefore, the steel strip 8 is
The oil floating on the surface of No. 1 is pressed by the hold down roll 98 when passing through the hold down roll 98 and adheres to the surface of the steel strip 81 again, which causes a problem that the degreasing effect is reduced. In addition, electrolytically degreased steel strip 8
When 1 passes through the holddown roll 98, oil also adheres to the surface of the holddown roll 98. Then, as the electrolytic degreasing is continuously performed, the amount of oil attached to the surface of the hold-down roll 98 increases and solidifies. Therefore, hold down roll 9
The oil content adhering to the surface of No. 8 redeposits on the surface of the steel strip 81 to stain the surface, and the oil content solidified on the surface of the hold-down roll 98 causes push flaws on the surface of the steel strip 81. There is. The present invention has been made in view of such circumstances, of the steel strip capable of maintaining a good degreased state of the surface of the steel strip by preventing re-adhesion of oil components and the occurrence of flaws on the steel strip after electrolytic degreasing. An object is to provide a horizontal degreasing device and a vertical degreasing device.

[0008]

According to a first aspect of the present invention, there is provided a horizontal degreasing device for a steel strip, which comprises an electrolytic degreasing means for degreasing oil adhering to the surface of the steel strip in a cleaning liquid, and an electrolytic degreasing means. Later in the horizontal degreasing device of the steel strip having a mechanical degreasing means for removing the oil content adhering to the surface of the steel strip with a brush roll, the steel strip on the downstream side of the electrode provided in the electrolytic degreasing means A pair of fluid nozzles for sandwiching and spraying fluid is provided. By installing a pair of fluid nozzles on the downstream side of the electrode provided in the electrolytic degreasing device, which sprays fluid from both sides across the steel strip that has passed through the electrolytic degreasing device, the cleaning liquid is suspended from the surface of the steel strip and floats. It is possible to prevent the cleaning liquid containing the oil to be taken out to the brush roll side. As a result, even if the cleaning liquid is scraped off by the brush roll, the cleaning liquid containing oil does not scatter.
Further, since the steel strip after electrolytic degreasing can be directly conveyed to the brush roll without passing through a support such as a roll, it is possible to prevent re-adhesion of the lifted oil component to the steel strip. Here, as the cleaning liquid, for example, an alkaline aqueous solution in which an alkali such as sodium hydroxide is dissolved can be used.
As the fluid ejected from the fluid nozzle, for example, a cleaning liquid such as air or nitrogen gas or a gas that does not react with the steel strip can be used, and the pressure when ejected from the fluid nozzle is 1.0 to 3.0 kg. / Cm ² G, the flow rate is 50 to 1
It can be set to 00 Nm ³ / min.

In the horizontal degreasing apparatus for steel strips according to the first aspect of the present invention, the electrodes, the fluid nozzles that make a pair, and the brush rolls are arranged in an inclined manner by sequentially increasing the respective installation positions, and the steel strips are arranged. It is preferable to convey the sheet from the lower side to the upper side with an inclination. The steel strip, which is sequentially arranged from the upstream side to the downstream side, the fluid nozzle that makes a pair, and the brush roll, can convey the steel strip obliquely from the lower side to the upper side within an angle range that does not affect the overall line layout. it can. For this reason, it is possible to prevent the cleaning liquid containing the floating oil component from being caught in the conveyance of the steel strip and carried out to the brush roll side by a weight effect.

According to a second aspect of the present invention, a vertical degreasing apparatus for a steel strip according to the present invention conveys a steel strip in the cleaning liquid in a vertical direction via a sink roll provided in a storage tank storing the cleaning liquid. It has an electrolytic degreasing means provided with an electrode for degreasing the oil content adhering to the surface of the steel strip, and a mechanical degreasing means for removing the oil content adhering to the surface of the steel strip after electrolytic degreasing with a brush roll. In the vertical degreasing device for steel strips, a fluid nozzle paired with the steel strips is provided on the downstream side of the electrodes arranged on the rear side of the sink roll. By providing a pair of fluid nozzles on the downstream side of the electrode disposed on the downstream side of the sink roll, which sprays a fluid for removing the cleaning liquid from both sides of the steel strip that has passed through the electrolytic degreasing means, the surface of the steel strip can be removed. It is possible to prevent the cleaning liquid containing the floating oil after the cleaning liquid is cut off from being taken out to the brush roll side. As a result, even if the cleaning liquid is scraped off by the brush roll, the cleaning liquid containing oil is not scattered. Further, since the steel strip after electrolytic degreasing can be directly conveyed to the brush roll side without passing through a support such as a roll, the oil content floating on the surface of the steel strip can be immediately scraped off without re-adhesion of oil content. Here, as the cleaning liquid, for example, an alkaline aqueous solution in which an alkali such as sodium hydroxide is dissolved can be used. As the fluid ejected from the fluid nozzle, for example, a cleaning liquid such as air or nitrogen gas or a gas that does not react with the steel strip can be used, and the pressure when ejected from the fluid nozzle is 1.0 to 3.
0 kg / cm ² G, flow rate 50-100 Nm ³ / min
Can be

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION Next, referring to the attached drawings, an embodiment in which the present invention is embodied will be described to provide an understanding of the present invention. 1 is a block diagram of a horizontal degreasing device for a steel strip according to a first embodiment of the present invention, and FIG. 2 is a configuration of a vertical degreasing device for a steel strip according to a second embodiment of the present invention. It is a figure. As shown in FIG. 1, the horizontal degreasing apparatus 10 for a steel strip according to the first embodiment of the present invention removes oil adhering to the surface of the steel strip 11 in a sodium hydroxide aqueous solution 12 which is an example of a cleaning liquid. At the electrolytic degreasing means 15 provided with two pairs of electrodes 13 and 14 which are floated by electrolysis, and the steel strip 11 is provided on the downstream side of the electrode 14 at the last stage,
Aqueous sodium hydroxide solution 12 existing around the steel strip 11
It has a pair of fluid nozzles 16 for ejecting air, which is an example of a fluid for removing water from the surface of the steel strip 11. Furthermore, the horizontal degreasing apparatus 10 for steel strips includes a mechanical degreasing means 19 including two pairs of brush rolls 17 and 18 for removing oil adhering to the surface of the steel strip 11 that has passed through the fluid nozzle 16.
And have. Hereinafter, these will be described in detail.

The sodium hydroxide aqueous solution 12 is prepared by dissolving 30 to 50 g of sodium hydroxide in 1 liter of water. And since the sodium hydroxide aqueous solution 12 manages the temperature at 57-63 degreeC,
Heating means such as an electric heater or steam pipe (not shown)
Is stored in the cleaning liquid tank 20 made of, for example, stainless steel. Further, a steel strip inlet 21 for introducing the steel strip 11 into the cleaning liquid bath 20 is provided at the lower part of one side of the cleaning liquid bath 20, and the cleaning liquid bath 20 is provided at the upper part of the other side of the cleaning liquid bath 20.
A steel strip lead-out port 22 for leading out the steel strip 11 from the inside is provided. Further, the stored sodium hydroxide aqueous solution 12
A seal roll 23 is provided inside the steel strip inlet 21, and a seal roll 24 is provided inside the steel strip outlet 22 to prevent the outflow of the steel strip. With such a configuration, the steel strip 1 is introduced from the steel strip inlet 21 into the cleaning liquid tank 20 storing the heated sodium hydroxide aqueous solution 12.
1 can be carried in and the steel strip 11 can be carried out from the steel strip outlet 22. At that time, the stored sodium hydroxide aqueous solution 12 can be prevented from flowing out.

In the cleaning liquid tank 20, the electrode 13, the electrode 14, the pair of fluid nozzles 16 and the brush roll are arranged from the seal roll 23 on the steel strip inlet 21 side toward the seal roll 24 on the steel strip outlet 22 side. 17 and the brush roll 18 are arranged in order, and further, they are arranged in an inclined manner (for example, the inclination angle is 10 to 30 °) so that the installation positions thereof are sequentially increased. With such a configuration, the steel strip 11 carried in through the seal roll 23 from the steel strip introduction port 21 below the cleaning liquid tank 20 is passed through the gaps between the electrodes 13 and 14 to form a pair of fluids. It is possible to perform an inclined conveyance in which the nozzle 16 is passed through, the brush rolls 17 and 18 are further passed, and the steel roll outlet 22 is carried out via the seal roll 24.

Here, the electrodes 13 and 14 are supported by a support not shown.
It is fixed in the cleaning liquid tank 20 with a member, and the
Applying a voltage from the power supply wiring not shown, each electrode 13, 14
For example, via an aqueous sodium hydroxide solution 12 interposed between
For example, 100-150 A / dm ² Flow current with current density of
You Therefore, the steel strip 11 passes through the gaps between the electrodes 13 and 14.
When one passes, one side of the electrodes 13 and 14 is paired with this one side.
An electric current flows between the facing steel strip 11 and the surface on one side,
The sodium oxide aqueous solution 12 is electrolyzed. this
At this time, one of the steel strips 11 facing one side of the electrodes 13 and 14
On the other side, different gases (on the anode side, oxygen gas
Hydrogen gas) is generated on the cathode side and the cathode side. Generation of this gas
Causes the oil content adhering to one surface of the steel strip 11 to float.
Rise up. At the same time, the other side of the electrodes 13 and 14 and this other side
Current also flows between the other side of the steel strip 11 and the opposite surface of the steel strip 11.
Electrolysis of the sodium hydroxide solution 12 is performed,
Of the other side of the steel strip 11 facing the other side of the electrodes 13, 14.
Different kinds of gas are generated on the surface, and this gas is generated.
Oil on the other side of the steel strip 11 floats
Go up. For this reason, sodium hydroxide containing floating oil
The steel strip 11 with the aqueous solution 12 on the surface is
It comes out of the electrode 14.

A pair of fluid nozzles 16 for ejecting air are
It is fixed in the cleaning liquid tank 20 by a supporting member (not shown), and the pressure of air is 1.0 to 10
3.0 kg / cm ² G, flow rate 50 to 100 Nm ³ / mi
n. Further, the fluid nozzle 16 is fixed such that the air discharge direction is directed perpendicularly to the surface of the steel strip 11 on which the air is conveyed, or on the upstream side in the conveying direction. Therefore, when air is sprayed from the fluid nozzle 16 onto the surface of the steel strip 11 after electrolytic degreasing by the electrolytic degreasing means 15, the aqueous sodium hydroxide solution 12 containing oil floating from the surface of the steel strip 11 can be removed by the air. it can.
As a result, it is possible to prevent the sodium hydroxide aqueous solution 12 containing floating oil from being carried out to the brush rolls 17 and 18. Furthermore, the electrodes 13, 14, the fluid nozzle 16,
Since the brush rolls 17 and 18 are arranged so as to be inclined in this order with the installation positions sequentially higher, the steel strip 11 can be conveyed from the lower side to the upper side, and the aqueous sodium hydroxide solution 12 containing the floating oil component is made of steel. It is possible to prevent, by a weight effect, being caught in the conveyance of the belt 11 and being taken out to the upper side of the brush rolls 17 and 18. Further, the two pairs of brush rolls 17 and 18 are support members (not shown), and the cleaning liquid tank 2
The rotation driving force is fixed in 0 and the rotation driving force is transmitted from a driving source (not shown) through a rotation force transmitting mechanism provided on the support member to rotate. Therefore, the steel strip 11 is attached to the brush roll 1
By sandwiching it with 7, 18, it is possible to scrape off oil adhering to the surface of the steel strip 11.

Next, a degreasing method for the steel strip 11 to which the horizontal degreasing apparatus 10 for steel strip according to the first embodiment of the present invention is applied will be described in detail. First, sodium hydroxide aqueous solution 12 to be a cleaning liquid is prepared by dissolving 30 to 50 g of sodium hydroxide in 1 liter of water. The prepared sodium hydroxide aqueous solution 12 is stored in the cleaning liquid tank 20, and the temperature of the sodium hydroxide aqueous solution 12 is adjusted to 57 to 63 ° C. by a heating means (not shown). Then 2
A voltage is applied between the electrodes 13 and 14 so that a current flows at a current density of 100 to 150 A / dm ² between the pair of electrodes 13 and 14. Further, the pressure of 1.0 is applied to the pair of fluid nozzles 16.
~ 3.0 kg / cm ² G, flow rate 50-100 Nm ³ / m
Air is supplied and discharged under the condition of in. Further, the two pairs of brush rolls 17 and 18 are rotated. Then, the seal roll 23 is rotated to move the steel strip introduction port 21 into the cleaning liquid tank 20.
The steel strip 11 is loaded from here.

First, the steel strip 11 is electrolytically degreased by the electrolytic degreasing means 15. When the steel strip 11 passes through the gap between the electrodes 13 and 14, an electric current flows between one side of the electrodes 13 and 14 and the one side surface of the steel strip 11 facing the one side, and sodium hydroxide is added. The aqueous solution 12 is electrolyzed. At this time, different kinds of gas (oxygen gas on the anode side and hydrogen gas on the cathode side) are generated on one surface of the steel strip 11 facing the one side of the electrodes 13 and 14, respectively. Due to the generation of this gas, the oil component attached to the one surface of the steel strip 11 floats. At the same time, a current also flows between the other side of the electrodes 13 and 14 and the surface of the other side of the steel strip 11 facing the other side to electrolyze the aqueous sodium hydroxide solution 12,
Different kinds of gas are generated on the other surface of the steel strip 11 facing the other side of the electrodes 13 and 14, respectively, and due to the generation of this gas, the oil component attached to the other surface of the steel strip 11 floats up. . Therefore, the steel strip 11 comes out of the electrode 14 in a state where the sodium hydroxide aqueous solution 12 containing floating oil is present on the surface.

When the steel strip 11 that has passed through the electrode 14 reaches the fluid nozzle 16, air is blown from the direction perpendicular to each surface of the steel strip 11 or toward the upstream side in the transport direction of the steel strip 11. By blowing air, the steel strip 11
The aqueous sodium hydroxide solution 12 containing floating oil that was present on the surface of the is blown off and replaced with the aqueous sodium hydroxide solution 12 containing no floating oil. Therefore, a sodium hydroxide aqueous solution containing floating oil 1
2 is not taken out to the brush rolls 17 and 18 side. Further, since the steel strip 11 is conveyed obliquely from below to above, the aqueous solution of sodium hydroxide 12 containing floating oil is
Is rolled up in the conveyance of the steel strip 11 and the upper brush roll 1
It is prevented from being brought out to the 7 and 18 side due to the weight effect. Next, mechanical degreasing is performed by the mechanical degreasing means 19. That is, the steel strip 11 in which the aqueous sodium hydroxide solution 12 containing no oil is present is sandwiched between the brush rolls 17 and 18, and the oil deposited on the surface of the steel strip 11 is scraped off. At this time, the sodium hydroxide aqueous solution 12 containing the floating oil component is brush roll 17,
18 is not taken out, so brush rolls 17 and 18
Even if the sodium hydroxide aqueous solution 12 is scraped off with, the oil does not redeposit on the steel strip 11. Brush roll 18
The steel strip 11 that has passed through is conveyed out of the cleaning liquid tank 20 from the steel strip outlet 22 via the seal roll 24, and is conveyed to the water spray (rinse) step.

As shown in FIG. 2, a steel strip vertical degreasing apparatus 25 according to a second embodiment of the present invention is a storage tank 26 in which an aqueous sodium hydroxide solution 12 as an example of a cleaning liquid is stored.
Electrolytic degreasing means provided with two pairs of electrodes 28, 29 for vertically transporting the steel strip 11 in a storage tank 26 via a sink roll 27 provided therein to electrolytically degrease oil adhering to the surface. Has 30. Here, the electrode 28 is upstream of the sink roll 27, and the electrode 29 is the sink roll 27.
Is provided on the downstream side of each. Further, the vertical degreasing device 25 for the steel strip is provided on the downstream side of the electrode 29 on the latter side of the sink roll 27 so as to sandwich the steel strip 11 after electrolytic degreasing, and the hydroxylation existing around the steel strip 11 is provided. It has a pair of fluid nozzles 31 for ejecting air, which is an example of a fluid for removing the sodium aqueous solution 12 from the surface of the steel strip 11. Further, the vertical degreasing device 25 for steel strip has a mechanical degreasing means 34 provided with two pairs of brush rolls 32, 33 for removing oil adhering to the surface of the steel strip 11 passing through the fluid nozzle 31. is doing. Hereinafter, these will be described in detail.

The storage tank 26 for storing the sodium hydroxide aqueous solution 12 is provided with a heating means (not shown) such as an electric heater or a steam pipe for controlling the temperature of the stored sodium hydroxide aqueous solution 12 to 57 to 63 ° C. ing. Here, the storage tank 26 can be formed of, for example, stainless steel. The steel strip 11 is provided on one side of the upper portion of the storage tank 26.
A deflector roll 36 that changes the conveying direction of the steel strip 11 for introducing the steel into the storage tank 26.
A sink roll 27 that reverses the conveying direction of the steel strip 11 is provided in the central portion on the lower side of the inside. On the other side of the upper part of the storage tank 26, the steel strip 11 drawn out from inside the storage tank 26.
A hold-down roll 37 that changes the transport direction of the sheet is provided. With such a configuration, the storage tank 26 that stores the heated sodium hydroxide aqueous solution 12
The steel strip 11 can be carried in through the deflector roll 36, and the steel strip 11 can be carried out of the storage tank 26 through the hold down roll 37.

In the storage tank 26, an electrode 28 on the upstream side and an electrode 29 on the downstream side of the sink roll 27 are fixed by a supporting member (not shown), respectively, and a voltage is supplied from a power source wiring (not shown) via the supporting member. It is hung. Aqueous sodium hydroxide solution 1 around the steel strip 11 and the electrodes 28, 29.
2 exists, the steel strip 11 is placed in the gap between the electrodes 28, 29.
Through the steel strip 11, a current flows at a current density of 100 to 150 A / dm ² between the electrodes 28 and 29, respectively, and the sodium hydroxide aqueous solution 12 is electrolyzed. As a result, the gas generated by the electrolysis becomes bubbles to lift up the oil content adhering to the surface of the steel strip 11.

The pair of fluid nozzles 31 for discharging air are
It is fixed in the storage tank 26 by a support member (not shown), and the pressure of air from the pipe (not shown) is 1.0 to 10 through the support member.
3.0 kg / cm ² G, flow rate 50 to 100 Nm ³ / mi
n. Further, the fluid nozzle 31 is fixed so that the air discharge direction is directed perpendicularly to the surface of the steel strip 11 on which the air is conveyed, or on the upstream side in the conveying direction. Therefore, when air is sprayed from the fluid nozzle 31 onto the surface of the steel strip 11 after electrolytic degreasing, the steel strip 11 is blown by the air.
It is possible to remove the sodium hydroxide aqueous solution 12 containing the oil floating from the surface of the. As a result, the sodium hydroxide aqueous solution 12 containing the floating oil is transferred to the brush roll 3
It can be prevented from being taken out to the 2, 33 side. Further, the two pairs of brush rolls 32 and 33 are fixed in the storage tank 26 by a supporting member (not shown), and a rotational driving force is transmitted from a driving source (not shown) through a rotational force transmitting mechanism provided in the supporting member to rotate the brush rollers 32 and 33. is doing. Therefore, the steel strip 11 is sandwiched between the brush rolls 32 and 33, and the oil component attached to the surface of the steel strip 11 is scraped off.

Next, a degreasing method for the steel strip 11 to which the vertical degreasing device 25 for steel strip according to the second embodiment of the present invention is applied will be described in detail. First, the sodium hydroxide aqueous solution 12 in which 30 to 50 g of sodium hydroxide is dissolved in 1 liter of water is stored in the storage tank 26, and the temperature of the sodium hydroxide aqueous solution 12 is set to 57 by a heating means (not shown). Adjust to ~ 63 ° C. Then two pairs of electrodes 2
A voltage is applied between the electrodes 28 and 29 so that a current flows at a current density of 100 to 150 A / dm ² between the electrodes 8 and 29. Moreover, the pressure of 1.0 to 3.0 is applied to the pair of fluid nozzles 31.
Air is supplied and discharged under the conditions of kg / cm ² G and a flow rate of 50 to 100 Nm ³ / min. Further, the two pairs of brush rolls 32 and 33 are rotated. Then, the steel strip 11 is carried into the storage tank 26 from above the storage tank 26 via the deflector roll 36.

The steel strip 11 carried into the storage tank 26 first passes through the gap between the electrodes 28, and at this time, one side of the electrode 28 and one surface of the steel strip 11 opposite to this one side. A current flows between them, and the sodium hydroxide aqueous solution 12 is electrolyzed. At this time, different kinds of gas (oxygen gas on the anode side and hydrogen gas on the cathode side) are generated on the one surface of the steel strip facing the one side of the electrode 28. Due to the generation of this gas, the oil component attached to the one surface of the steel strip 11 floats. At the same time, an electric current also flows between the other side of the electrode 28 and the other side surface of the steel strip 11 facing the other side, so that the aqueous sodium hydroxide solution 12 is electrolyzed and faces the other side of the electrode 28. Different kinds of gas are generated on the other surface of the steel strip 11, and the oil attached to the other surface of the steel strip 11 floats up due to the generation of this gas.
The steel strip 11 that has passed through the electrode 28 is transported upward through the sink roll 27 with its transport direction reversed, and passes through the gap between the electrodes 29. At this time, the electrode 29 and the steel strip 1
The aqueous sodium hydroxide solution 12 existing between 1 and 1 is electrolyzed, and the generated gas floats up the oil components attached to both surfaces of the steel strip 11. As a result, the steel strip 11 emerges from the electrode 29 in a state where the sodium hydroxide aqueous solution 12 containing floating oil is present on the surface.

When the steel strip 11 that has passed through the electrode 29 reaches the fluid nozzle 31, air is blown from the direction perpendicular to each surface of the steel strip 11 or toward the upstream side in the transport direction. By blowing the air, the sodium hydroxide aqueous solution 12 containing the floating oil component existing on the surface of the steel strip 11 is blown off. For this reason, the sodium hydroxide aqueous solution 12 containing the floating oil is transferred to the brush roll 32,
It is not taken out to the 33 side. Next, the steel strip 11 is sandwiched between the brush rolls 32 and 33, and the oil component adhering to the surface of the steel strip 11 is scraped off. At this time, the sodium hydroxide aqueous solution 12 containing the floating oil is brush roll 32,
Since it is not taken out to the 33 side, brush rolls 32, 33
Even if the sodium hydroxide aqueous solution 12 is scraped off with, the oil does not redeposit on the steel strip 11. Brush roll 33
The steel strip 11 that has passed through is carried out of the storage tank 26 through the hold-down roll 37 and is conveyed to the water spray (rinse) step.

[0026]

[Example] Horizontal degreasing apparatus for steel strip 1 according to the above embodiment
0 was used to degrease the steel strip 11. An aqueous sodium hydroxide solution 12 prepared by dissolving 30 g of sodium hydroxide in 1 liter of water is placed in the cleaning liquid tank 20 at a temperature of 60.
It was adjusted to ℃ and stored. 100A / between electrodes 13 and 14
A voltage was applied so that current would flow at a current density of dm ² .
Further, air was supplied to the fluid nozzle 16 at a pressure of 1.5 kg / cm ² G and a flow rate of 70 Nm ³ / min for ejection. Next, a steel strip 11 having a thickness of 0.4 mm and a width of 600 mm
Horizontal degreasing device 10 for steel strips at a conveying speed of 100 m / min
I passed through. The degreased state was judged by visually observing the surface of the steel strip 11 after degreasing with the horizontal degreasing device 10 for the steel strip. In addition, water wettability was determined using a 100 × 100 mm steel strip sample. Furthermore, the surface of the steel strip 11 is 100 cm
^It was wiped off with a cloth containing hexane over the range of ² , and the amount of oil transferred to hexane was quantified by infrared absorption spectroscopy to calculate the amount of residual oil per 1 m ² . Also,
As a comparative example, the conventional horizontal degreasing device 8 for a steel strip shown in FIG.
No. 0, an electrolytic degreasing tank 83 was used for the aqueous sodium hydroxide solution under the same conditions as in the case of the horizontal degreasing apparatus 10 for a steel strip of this example.
Stored in a steel strip 81, and a current is passed through the electrode 85 at a current density of 100 A / dm ² to obtain a steel strip 81 having a thickness of 0.4 mm and a width of 600 mm.
Was passed at a transportation speed of 100 m / min. Comparing the degreased states, in the case of this example, no oil residue was observed on the surface, the degreased state was good, the water wettability was 100%, and the residual oil amount was 3 mg / m ² . On the other hand, in the comparative example, the oil content remained on the surface and the degreasing state was poor, the water wettability was 60%, and the residual oil content was 6 mg / m ² .

The embodiment of the present invention has been described above.
The present invention is not limited to this embodiment,
Modifications are possible without changing the gist of the invention, and the horizontal degreasing device and the vertical degreasing device for a steel strip of the present invention are configured by combining some or all of the above-described embodiments and modifications. In this case, the present invention also applies. For example,
Although the fluid discharged from the fluid nozzle is air, nitrogen gas may be discharged. Further, although one pair of fluid nozzles is provided, a plurality of pairs of fluid nozzles may be provided. Two pairs of electrodes and brush rolls are provided, but one pair or three or more pairs may be provided depending on the situation. Further, although the sodium hydroxide aqueous solution was used as the cleaning liquid, it is also possible to use the sodium orthosilicate aqueous solution and the potassium hydroxide aqueous solution.

[0028]

In the horizontal degreasing device for steel strips according to the first and second aspects, a pair of fluid nozzles for spraying fluid with the steel strip sandwiched is provided downstream of the electrode provided in the electrolytic degreasing means. Therefore, it is possible to prevent the cleaning liquid containing floating oil from being taken out to the brush roll side, and it is possible to prevent the steel strip from being contaminated due to the redeposition of the floating oil due to electrolytic degreasing. It is possible to improve the effect. Further, since the cleaning water containing a large amount of oil does not scatter even when the brush roll is operated, it is possible to facilitate the maintenance of the cleaning liquid tank, for example. Further, the steel strip after electrolytic degreasing can be conveyed as it is to the brush roll, and it becomes possible to improve the efficiency of mechanical degreasing of the steel strip by the brush roll, and the steel strip after electrolytic degreasing has a flaw. It is possible to prevent the occurrence.

In particular, in the horizontal degreasing apparatus for steel strips according to the second aspect, the electrodes, the fluid nozzles that make a pair, and the brush rolls are arranged in a slanting manner by sequentially increasing the respective installation positions, and the steel strips are arranged from below. Since the sheet is conveyed upward with an inclination, it is possible to prevent the cleaning liquid containing the oil floating due to the weight effect from being taken out to the brush roll side.

In the vertical degreasing apparatus for steel strips according to the third aspect of the present invention, the pair of fluid nozzles sandwiching the steel strips is provided on the downstream side of the electrode arranged on the downstream side of the sink roll, so that it floats. It is possible to prevent the cleaning liquid containing oil from being taken out to the brush roll side, and it becomes possible to prevent the steel strip from being contaminated by the oil suspended by electrolytic degreasing.
It is possible to improve the effect of degreasing cleaning. Further, since the cleaning water containing a large amount of oil does not scatter even when the brush roll is operated, maintenance of the storage tank can be facilitated. Furthermore, the steel strip after electrolytic degreasing can be conveyed to the brush roll as it is, and the efficiency of mechanical degreasing of the steel strip by the brush roll can be improved.
As a result, it is possible to prevent oil from adhering to the support of the steel strip such as the hold-down roll, and to prevent contamination due to redeposition of oil when the degreased steel strip passes through the hold-down roll, It is possible to prevent the occurrence of flaws.

[Brief description of drawings]

FIG. 1 is a configuration diagram of a horizontal degreasing device for steel strips according to a first embodiment of the present invention.

FIG. 2 is a configuration diagram of a vertical degreasing device for steel strips according to a second embodiment of the present invention.

FIG. 3 is a configuration diagram of a conventional horizontal degreasing device for steel strips.

FIG. 4 is a block diagram of a conventional vertical degreasing device for steel strips.

[Explanation of symbols]

10: Horizontal degreasing device for steel strip, 11: Steel strip, 12: Aqueous sodium hydroxide solution, 13, 14: Electrode, 15: Electrolytic degreasing means, 16: Fluid nozzle, 17, 18: Brush roll,
19: Mechanical degreasing means, 20: Cleaning liquid tank, 21: Steel strip inlet, 22: Steel strip outlet, 23, 24: Seal roll,
25: Vertical degreasing device for steel strip, 26: Storage tank, 27: Sink roll, 28, 29: Electrode, 30: Electrolytic degreasing means, 3
1: Fluid nozzle, 32, 33: Brush roll, 34: Mechanical degreasing means, 36: Deflector roll, 37: Hold down roll

Claims (3)

[Claims] 1. An electrolytic degreasing means for degreasing an oil component adhering to the surface of a steel strip in a cleaning liquid, and a mechanical degreasing device for removing the oil component adhering to the surface of the steel strip after electrolytic degreasing with a brush roll. In a horizontal degreasing device for a steel strip having means, a pair of fluid nozzles for spraying a fluid sandwiching the steel strip is provided on the downstream side of an electrode provided in the electrolytic degreasing means. Horizontal degreasing device. 2. The horizontal degreasing device for a steel strip according to claim 1, wherein the electrodes, the fluid nozzles forming the pair, and the brush rolls are arranged in an inclined manner with respective installation positions being sequentially increased. A horizontal degreasing device for steel strips, which conveys slant from the bottom to the top. 3. An electrode for degreasing oil adhered to the surface of the steel strip by vertically conveying the steel strip in the cleaning fluid via a sink roll provided in a storage tank storing the cleaning fluid. In the vertical degreasing device for a steel strip, which has an electrolytic degreasing means and a mechanical degreasing means for removing the oil content adhering to the surface of the steel strip after the electrolytic degreasing with a brush roll, the vertical degreasing device is arranged on the rear side of the sink roll. A vertical type degreasing device for a steel strip, characterized in that a fluid nozzle paired with the steel strip sandwiched is provided on the downstream side of the formed electrode.