KR101294017B1 - A vacuum pressure suction roll with improved suction efficiency - Google Patents

Abstract

PURPOSE: A vacuum suction roll with improved suction efficiency is provided to focus vacuum pressure on a portion in which the cleaning solution of a target object is existed and to prevent the vacuum pressure from being actuated on a portion in which the suction efficiency is low, thereby improving the suction efficiency. CONSTITUTION: A vacuum suction roll with improved suction efficiency includes a vacuum suction pipe (20), a middle tube (30), an elastic fiber layer (40), a suction direction setting member (50), and a bearing (60). The middle tube is installed separately from the vacuum suction pipe at a predetermined interval. A plurality of holes (31) connecting the inside and the outside is arranged on the periphery of the middle tube. The suction direction setting member includes a blade dividing a space so that the suction pressure of the vacuum suction pipe is focused on a preset area of the inner circumference of the middle tube. The bearing freely rotates the suction direction setting member so that the suction direction setting member always faces a predetermined direction by the self weight thereof between the suction direction setting member and the middle tube.

Description

A vacuum pressure suction roll with improved suction efficiency

The present invention relates to a vacuum suction roll with improved suction efficiency, by suctioning the cleaning liquid, etc. buried on the surface of the strip-shaped product using a vacuum pressure to concentrate the suction pressure in the region where the cleaning liquid is present in the strip-shaped product It relates to a vacuum suction roll configured to increase.

In the wet process for processing and cleaning steel strips and manufacturing semiconductor substrates, a vacuum suction roll is used to finally absorb the detergent, water, oil, etc. on the surface of the product.

FIG. 1 shows a configuration of a vacuum suction roll which absorbs a cleaning liquid, a neutralizing agent, and the like on the surface of a steel sheet strip 9 as disclosed in Korean Utility Model Publication No. 1999-0018413.

Referring to FIG. 1, the first vacuum suction roll 1 and the second vacuum suction roll 2 are in contact with each other on the upper side and the lower side of the steel strip 9, and the first vacuum suction is performed with the progress of the steel sheet strip 9. The roll 1 and the second vacuum suction roll 2 are rotating.

The cleaning liquid 8 or the like buried on the surface of the steel strip 9 during the course of the steel strip strip 9 is provided in the first vacuum suction roll 1 and the second vacuum suction roll 2 of the nonwoven fabric 3. Can be absorbed by.

The first vacuum suction roll (1) and the second vacuum suction roll (2) are arranged in a tubular shape with a plurality of absorption cells (4) are installed at uniform intervals along the circumference inside the nonwoven fabric (3) of the outer peripheral surface, In the absorption cell 4, a space portion 5 in which a vacuum pressure is formed is formed.

Accordingly, when a vacuum pressure is applied to the space 5 by an external vacuum pump, the cleaning liquid 8 and the like adsorbed on the nonwoven fabric 3 may be sucked into the space 5 through the absorption cell 4. have. The fluid sucked into the space 5 may be reused by being recovered from an external vacuum tank.

However, looking at the structure and action of the conventional suction cups (1, 2), the suction force generated by the vacuum pump acts evenly along the circumference of the nonwoven fabric (3) through the absorption cell (4) to suck the cleaning liquid The suction efficiency is inevitably lowered.

That is, the portion in which a large amount of the cleaning liquid is sucked from the vacuum suction rolls 1 and 2 is an area where the nonwoven fabric 3 is in contact with the steel sheet strip 9, and the vacuum suction rolls 1 and 2 located at a position away from the steel sheet strip 9. In the outer region of 2), the amount of suction of some cleaning liquid adsorbed on the nonwoven fabric 5 is not large, so that the suction pressure is evenly applied to the entire circumference of the vacuum suction rolls 1 and 2 to increase the suction efficiency. It causes the deterioration.

The present invention has been made in view of the above problems, an object of the present invention is to limit the area in which the suction force acts to concentrate the vacuum pressure in the region where the cleaning liquid is present in the strip-shaped product to improve the suction efficiency It is to provide a suction roll.

In order to achieve the above object, the present invention, in the vacuum suction roll for sucking the cleaning liquid, is installed in the center along the rotation axis and the vacuum suction tube generating a suction pressure, and in a state maintaining a constant interval with the vacuum suction tube The vacuum suction tube is installed inside and the intermediate tube is a plurality of holes that connect the inner and the outside is distributed along the circumference, the porous elastic fiber layer attached to surround the outer surface of the intermediate tube to form a roll-shaped outer surface Including, but between the vacuum suction pipe and the intermediate tube is installed on both sides of the wings extending along the rotation axis direction suction direction separating the space so that the suction pressure of the vacuum suction tube is concentrated in the set area of the inner peripheral surface of the intermediate tube A setting member, and installed between the suction direction setting member and the intermediate tube, the suction direction setting member Always facing the predetermined direction by its own weight is characterized in that a bearing for free rotation.

In addition, the present invention is the bearing is fixed to the outer ring on the inner peripheral surface of the intermediate tube, the vacuum suction pipe is fixed to the inner ring of the bearing, the suction direction setting member is fixed to the vacuum suction pipe integral with the vacuum suction pipe Rotating in, the suction port of the vacuum suction pipe is characterized in that located between the wings on both sides.

In addition, the present invention is the vacuum suction tube is fixed together with the intermediate tube, the vacuum suction tube has a plurality of suction ports are distributed along the circumference, the bearing is the inner ring is fixed to the vacuum suction tube, the outer ring is the suction direction setting member Is fixed to the suction direction setting member is characterized in that the other free rotation of the vacuum suction tube.

In another aspect, the present invention is characterized in that the suction direction setting member is formed more heavily on one side of the wings on both sides so that the set area is deflected laterally.

In the above configuration, the suction direction setting member has a shape in which the blades on both sides are formed by bending the plate body symmetrically around the vacuum suction pipe, and is further biased from the lower side to the rear side of the vacuum suction roll. .

In the vacuum suction roll according to the present invention as described above, the suction efficiency can be improved by concentrating the vacuum pressure to the portion where the cleaning liquid is present in the steel strip which is the object of work, and blocking the vacuum pressure action at the lower suction efficiency.

In particular, the suction direction setting member is formed on one side of the wings on both sides to make the vacuum pressure to be deflected from the lower side to the rear side of the vacuum suction roll based on the traveling direction of the steel strip, etc. Vacuum pressure can be concentrated. This can minimize the cleaning liquid that can remain by allowing the suction to be concentrated with a strong suction force before passing through the vacuum suction roll while the cleaning liquid is attached to the surface of the steel strip.

1 is a block diagram of a vacuum system for cleaning liquid absorption for a conventional strip-shaped product
Figure 2 is a cross-sectional view of the vacuum suction roll according to an embodiment of the present invention
3 is an enlarged cross-sectional view showing a portion in which a suction direction setting member is installed in a vacuum suction roll according to an embodiment of the present invention;
Figure 4 is a perspective view showing the cross-sectional configuration of the transverse direction for the vacuum suction roll according to an embodiment of the present invention
5 (a) and 5 (b) are perspective views showing the configuration of the suction direction setting member in the vacuum suction roll according to the embodiment of the present invention.
6 is an explanatory diagram illustrating the operation of the vacuum suction roll according to the embodiment of the present invention;
Figure 7 is a cross-sectional view of the vacuum suction roll according to another embodiment of the present invention
8 is an enlarged cross-sectional view showing a portion in which a suction direction setting member is installed in a vacuum suction roll according to another embodiment of the present invention;
Figure 9 is a cross-sectional configuration of the transverse direction for the vacuum suction roll according to an embodiment of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described in detail with reference to the drawings.

Figure 2 is a cross-sectional configuration of the vacuum suction roll according to an embodiment of the present invention, Figure 3 is an enlarged cross-sectional view showing a portion in which the suction direction setting member is installed in the vacuum suction roll according to an embodiment of the present invention, Figure 4 Is a perspective view showing a cross-sectional configuration of the transverse direction with respect to the vacuum suction roll according to an embodiment of the present invention.

2 to 4, the vacuum suction roll according to an embodiment of the present invention, the vacuum suction pipe 20 is installed in the center along the rotating shaft 11 to generate a suction pressure, and the vacuum suction pipe 20 and The vacuum tube 20 is installed in the state maintaining a constant interval inside the intermediate tube 30 and a plurality of holes 31 for connecting the inside and the outside are distributed along the circumference, and the intermediate tube 30 The space is divided so that the porous elastic fiber layer 40 attached to surround the outer surface to form a roll-shaped outer surface and the suction pressure of the vacuum suction tube 20 are concentrated in the set area of the inner circumferential surface of the intermediate tube 30. It includes a suction direction setting member 50, and a bearing 60 for supporting the suction direction setting member 50 between the suction direction setting member 50 and the intermediate tube (30).

The vacuum suction pipe 20 is a portion where the suction action is generated by the vacuum pressure inside the vacuum suction roll, and is installed on the innermost side of the rotary shaft 11 of the vacuum suction roll. The vacuum suction pipe 20 is connected to the vacuum pressure generator 75 in the lateral direction to transfer the vacuum pressure to the inside of the vacuum suction roll.

3, in this embodiment, the vacuum suction pipe 20 is installed so as not to contact the flange member 13 provided on both sides of the vacuum suction roll, and is supported by the bearing 60 so as to allow free rotation. In spite of the rotation of the roll, the vacuum suction pipe 20 may not be rotated. That is, the vacuum suction pipe 20 is partially inserted into the center hole 14 of the flange member 13 in the lateral direction and communicated with each other, but does not interfere with each other because they do not contact the flange member 13, the flange member 13 And the gap between the outer surface of the end side of the vacuum suction pipe 20 are made to be minute to minimize the loss of vacuum pressure without interfering with each other.

The intermediate tube 30 is installed to surround the vacuum suction tube 20 concentrically while maintaining a constant interval with the vacuum suction tube 20. Accordingly, an empty space is formed between the vacuum suction tube 20 and the intermediate tube 30 and a space in which the suction direction setting member 50 can pivot is provided. Since the plurality of holes 31 are evenly distributed along the circumference of the intermediate tube 30, a vacuum pressure capable of absorbing the cleaning liquid 72 from the elastic fiber layer 40 installed on the outside thereof may act.

The elastic fiber layer 40 is attached to surround the outer surface of the intermediate tube 30 to form a roll-shaped outer surface. The elastic fiber layer 40 can be formed by winding a nonwoven fabric on the outer surface of the intermediate tube 30, or by laminating the fiber disk in the rotational axis direction to the outer surface of the intermediate tube 30 in sequence.

Since the elastic fiber layer 40 is made of a fiber material and is porous, the elastic fiber layer 40 can absorb the cleaning liquid 72 and has elasticity so that elastic deformation is possible when contacting the surface of the steel strip 71 to be worked.

The suction direction setting member 50 has wings 51 and 52 on both sides that move in an empty space between the vacuum suction tube 20 and the intermediate tube 30. The wings 51 and 52 on both sides serve to divide the space so as to surround the setting area where the suction pressure of the vacuum suction pipe 20 is concentrated. That is, the wings 51 and 52 on both sides form a plate shape extending in the rotation axis direction, respectively, and are spaced apart so that the wings 51 and 52 on both sides form an acute angle at a predetermined angle from each other in a cross section perpendicular to the rotation axis direction. A setting area is formed in the

The overall shape of the suction direction setting member 50 is a vacuum suction pipe in a state in which a plate-like body, such as a length of an empty space between the vacuum suction pipe 20 and the intermediate tube 30, is placed on the vacuum suction pipe 20 based on the rotation axis direction. It is a shape in which the wings 51 and 52 of both sides are formed by bending in the left-right symmetry about 20.

The suction direction setting member 50 is fixed integrally with the vacuum suction tube 20 to move together with the vacuum suction tube 20. The suction port 22 of the vacuum suction pipe 20 is positioned between the blades 51 and 52 on both sides so that the vacuum pressure can be applied in the setting region defined by the blades 51 and 52 on both sides.

In addition, the suction direction setting member 50 of the present invention forms one side of the wings 51, 52 on both sides more heavily so that the setting region is a lower region deflected laterally.

Referring to FIG. 5 (a), one of the wings 51 and 52 on both sides is attached to the wings 51 on one side of the wings 51 and 52 so as to extend in the rotational axis direction. It is configured to be heavier and the direction in which the wings 51 and 52 on both sides open is directed toward the lower region deflected to the other side of the lower direction. This is so that the direction in which the vacuum pressure concentrates acts in the direction in which the plurality of cleaning liquids 72 are collected. The weight of one wing may be increased by increasing the thickness of one wing without attaching a separate weight (54).

FIG. 5B shows the suction direction setting member 50 provided on the lower vacuum suction roll such as the steel strip 71 to be worked.

In this case, the weight 55 is attached to a position slightly biased to one side between the wings 51 and 52 on both sides, so that the vacuum pressure can be concentrated toward the upper rear as shown in FIG. 6.

On the other hand, the bearing 60 is installed between the suction direction setting member 50 and the intermediate tube 30, the suction direction setting member 50 to support the suction direction setting member 50 is always due to its own weight Free rotation to face a certain direction.

In this embodiment, the bearing 60 is installed between the suction direction setting member 50 and the intermediate tube 30 via the vacuum suction pipe 20 as shown in FIG. Accordingly, the suction direction setting member 50 is coupled to the inner ring 61 of the bearing 60 via the vacuum suction pipe 20, and the outer ring 62 of the bearing 60 is connected to the intermediate tube 30. In a coupled state, the suction direction setting member 50 and the vacuum suction tube 20 may freely rotate by the bearing 60 with respect to the intermediate tube 30.

6 is an explanatory view for explaining the operation of the vacuum suction tube 20 according to an embodiment of the present invention.

Referring to FIG. 6, the vacuum suction roll is in contact with the upper and lower sides of the steel strip 71 and the like, which is the object to be worked, and rotates together with the progress of the steel strip 71.

At this time, the cleaning liquid 72 and the like buried on the surface of the steel strip 71 is partially absorbed by the elastic fiber layer 40 and the rest of the cleaning liquid 72 is pushed to the rear side of the vacuum suction roll while the large amount of the cleaning liquid 72 is separated from the elastic fiber layer 40. The steel strip strips 71 accumulate on the rear side of the contact point. The portion “A” of the elastic fiber layer 40 corresponding to the area is a portion of the elastic fiber layer 40 that comes out of the cleaning liquid 72 that has been absorbed while the elastic fiber layer 40 starts to be pressed onto the surface of the steel strip 71. For reference, the “B” portion of the elastic fiber layer 40 is a portion of the elastic fiber layer 40 that has been pressed onto the steel strip 71 so as to be restored from the steel strip 71 with rotation. It is an area that can absorb strongly.

In this embodiment, the suction direction setting member 50 causes the vacuum pressure to be concentrated in the rear region of the vacuum suction roll in which the cleaning liquid 72 is collected so as to strongly suck the large amount of the cleaning liquid 72, and passes through the vacuum suction roll. The cleaning liquid 72 remaining on the surface of the steel strip 71 is minimized. If a large amount of the cleaning liquid 72 is accumulated in the steel strip 71 immediately before entering the vacuum suction roll, and the cleaning liquid 72 cannot be sufficiently absorbed, the steel sheet strip in the process of passing through the vacuum suction roll. The possibility of passage of the cleaning liquid 72 remaining on the surface of 71 becomes high.

Accordingly, the present invention improves the overall efficiency and performance by concentrating the vacuum pressure on the portion where the cleaning liquid 72 is present in the steel strip 71 as the work target and blocking the vacuum pressure action in the portion having low suction efficiency.

In particular, the suction direction setting member 50 is formed on one side of the wings (51, 52) on both sides to be more heavy, so that the contact portion between the vacuum suction roll and the steel strip (71) based on the traveling direction of the steel strip (71), etc. It is comprised so that it may face the direction deflected to the side.

As described above, the vacuum pressure is concentrated in the rear region of the vacuum suction roll in which the cleaning liquid 72 accumulates, so that the steel strip 71 covered with the cleaning liquid 72 can be sufficiently sucked before passing through the vacuum suction roll. To minimize the cleaning liquid 72 that may remain while passing through the vacuum suction roll.

The porous elastic fiber layer 40 in contact with the steel strip 71 is compressed and the microcavity of the inside is reduced, so that the absorption rate of the cleaning liquid 72 is significantly reduced. Therefore, when the elastic fiber layer 40 inhales the cleaning liquid 72 by concentrating a vacuum pressure before contacting the steel sheet strip 71 and compresses it, the cleaning liquid 72 easily passes through the elastic fiber layer 40 and the vacuum suction pipe. Since 20 can enter, a large amount of cleaning liquid 72 can be sucked in a short time. Since the direction in which the suction direction setting member 50 is biased toward the rear side of the lower part is in a state immediately before the elastic fiber layer 40 is compressed, the microcavity of the elastic fiber layer 40 is sufficiently left to facilitate the passage of the cleaning liquid 72. It is a state.

On the other hand, Figure 7 is a cross-sectional configuration of the vacuum suction roll according to another embodiment of the present invention, Figure 8 is an enlarged portion of the suction direction setting member 50 'in the vacuum suction roll according to another embodiment of the present invention. 9 is a cross-sectional view in the transverse direction with respect to the vacuum suction roll according to the embodiment of the present invention.

7 to 9, in this embodiment, the vacuum suction pipe 20 is configured to be fixed together with the intermediate tube 30, and the suction direction setting member 50 ′ can independently move by the bearing 60. It was configured to be.

That is, both ends of the vacuum suction tube 20 are fitted into the center hole 14 of the flange member 13 so that the vacuum suction tube 20 is coupled to the flange member 13 and the flange member 13 and the intermediate tube 30. Rotate integrally with A bearing 60 is installed in the vacuum suction pipe 20, but the vacuum suction pipe 20 is coupled to the inner ring 61 of the bearing 60, and the suction direction setting member 50 ′ is attached to the outer ring 62 of the bearing 60. Attached to the vacuum suction tube 20 can be freely rotated.

Since the gap between the suction direction setting member 50 'and the vacuum suction pipe 20 is generated by the height of the bearing 60, the vacuum suction pipe 20 has a plurality of suction holes 24 formed along the suction direction. A vacuum pressure is applied to the space surrounded by the setting member 50 '.

In this embodiment, the suction direction setting member 50 is attached to one of the wings (51, 52) on both sides so that the weight (54) is extended in the rotational axis direction, one side of the wings (51, 52) on both sides is more It is formed heavily.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the particular embodiments set forth herein. It goes without saying that other modified embodiments are possible.

11; Axis of rotation 13; Flange member
14; Central hole 20; Vacuum suction pipe
22; Inlet 24; Suction hole
30; Intermediate tube 31; hole
40; Elastic fiber layer 50; Suction direction setting member
50 '; Suction direction setting members 51 and 51; wing
54; Weight 60; bearing
61; Inner ring 62; paddle
71; Steel strip 72; Cleaning liquid
75; Vacuum pressure generator

Claims (5)

In the vacuum suction roll for sucking the cleaning liquid 72 on the strip-shaped product surface,
A vacuum suction pipe 20 installed at the center along the rotating shaft 11 to generate suction pressure,
The intermediate tube 30 having the vacuum suction pipe 20 installed inside the vacuum suction pipe 20 and having a plurality of holes 31 connecting the inner side and the outer side of the vacuum suction tube 20. ,
It includes a porous elastic fiber layer 40 attached to surround the outer surface of the intermediate tube 30 to form a roll-shaped outer surface,
Between the vacuum suction tube 20 and the intermediate tube 30, wings 51 and 52 on both sides extending along the rotational axis direction are installed, so that the suction pressure of the vacuum suction tube 20 is increased. A suction direction setting member 50 for dividing the space so as to concentrate on the setting area of the inner circumferential surface;
A bearing for supporting the suction direction setting member 50 between the suction direction setting member 50 and the intermediate tube 30 to freely rotate so that the suction direction setting member 50 always faces a certain direction by its own weight. Including (60),
The suction direction setting member 50
Vacuum suction roll, characterized in that one side of the wings 51, 52 on both sides is formed to be heavier so that the set area is deflected laterally The method of claim 1,
The bearing 60 is fixed to the outer ring 62 on the inner circumferential surface of the intermediate tube 30,
The vacuum suction pipe 20 is fixed to the inner ring 61 of the bearing 60,
The suction direction setting member 50 is fixed to the vacuum suction tube 20 to rotate integrally with the vacuum suction tube 20,
The suction port 22 of the vacuum suction pipe 20 is positioned between the blades 51 and 52 on both sides of the vacuum suction roll. The method of claim 1,
The vacuum suction tube 20 is fixed together with the intermediate tube 30,
The suction hole 24 is installed in the vacuum suction pipe 20,
The bearing 60 has an inner ring 61 fixed to the vacuum suction pipe 20, and an outer ring 62 is fixed to the suction direction setting member so that the suction direction setting member freely rotates with respect to the vacuum suction pipe 20. Vacuum suction roll, characterized in that 4. The method according to any one of claims 1 to 3,
The suction direction setting member 50
The plate-shaped body is bent in a symmetrical direction around the vacuum suction pipe 20 so that the wings 51 and 52 on both sides are formed, and the vacuum suction roll is characterized in that it is deflected from the lower side to the rear side of the vacuum suction roll. delete

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