KR20000011584U - Process solution-containing foreign substance removal device - Google Patents

Abstract

The present invention relates to a device for removing foreign matter contained in a process solution, a hollow member having both ends open and a housing having a plurality of longitudinal cutouts formed on the surface thereof, and a plurality of connecting legs at both ends of the housing. It is fixed to the inner surface of the housing through both ends are exposed to the outside of the housing screw rods respectively contained in the bearing block fixed on the opposite frame of the process solution tank, mounted on a support installed on one side of the process solution tank In connection with the exposed end of the screw bar, the drive unit rotates the housing and the screw bar, and only the foreign substances contained in the process solution are fixed to the housing surface so as to correspond to the plurality of cutouts formed on the surface of the housing, and then flow into the housing through the cutout. Each filtering member is semicircular in cross section with an empty space inside. The bottom part and the front part are open over the entire length, and a plurality of openings are formed in the back part.

Description

Process solution-containing foreign substance removal device

The present invention relates to an apparatus for removing foreign matter contained in a process solution in a process solution tank.

In general, the galvanizing process for the cold rolled strip to produce a plated product. Immediately before the galvanizing process, the coil work and pickling process for the strips are carried out and then heated in a furnace to be transferred to the galvanizing process. After strip galvanizing, shape correction, chrome coating and oiling, the strip is cut to the desired specifications and then wrapped by winding.

In the above-mentioned process, in the cold rolling process performed after the hot rolling process, the strip is plated with zinc (Zn) on its surface while passing through a heating furnace and a zinc plating bath. At this time, the liquid zinc on the surface of the strip (1) by using the air injected from the air knife (2; air knife) in order to meet the amount of plating required by the consumer in the galvanizing process proceeds as shown in Figure 1 and 2 Some will be removed. However, a zinc oxide lump (hereinafter referred to as "top dross") is formed on the liquid surface of the plating liquid by an oxidation reaction between the hot liquid zinc contained in the plating bath 10 and the cold air injected from the knife.

The top dross formed as described above causes scratches on the surface of the strip 1 where the plating process is performed, and also causes liquid zinc to splash. Therefore, the quality of the product by dross is accompanied by the risk of safety accidents by splashing liquid zinc. In order to prevent this, the operator must manually remove the dross in the plating bath, but in this case, the operator may be burned on the face by the scattered top dross.

The present invention is to solve the problems caused by the top dross formed during the galvanizing process, the top dross formed during the plating process to automatically remove the top dross present in the zinc solution. The purpose is to provide a loss removal device.

The present invention can be applied to remove foreign substances present in all process solutions as well as top dross generated in the galvanizing process.

The present invention for realizing the above object is a hollow member having both ends open, the housing having a plurality of longitudinal cutouts formed on the surface thereof, and fixed to the inner surface of the housing through a plurality of connecting legs at both ends of the housing. Both ends thereof are exposed to the outside of the housing and are respectively accommodated in a screw bar accommodated in a bearing block fixed on an opposing frame of the process solution tank, and are mounted on a support installed on one side of the process solution bath and exposed ends of the screw bar. A driving part connected to the rotating part to rotate the housing and the screw bar, and a plurality of filtering members respectively fixed to the surface of the housing so as to correspond to the plurality of cutouts formed on the surface of the housing to introduce only foreign substances contained in the process solution into the housing through the cutout; Located at the other side of the process solution tank with the drive unit is discharged to one end of the housing It consists of a collecting part for collecting foreign substances.

Each filtering member is a semicircular member having an empty space inside, the bottom and the front part are open over the entire length, and a plurality of openings are formed in the rear part.

1 is a block diagram of a general hot dip galvanizing apparatus.

Figure 2 is a schematic diagram for explaining the plating process using a hot dip galvanizing apparatus.

3 is a block diagram of a hot dip galvanizing apparatus using the present invention.

4 is a detailed view of the present invention.

5 is a perspective view of a housing used in the present invention.

6 is a perspective view of a filtering member fixed to the housing.

7 is a perspective view of a screw bar mounted in a housing.

Hereinafter, with reference to the accompanying drawings of the present invention will be described in detail.

3 is a schematic view of a hot dip galvanizing apparatus using the present invention, and the present invention is mounted in a general zinc plating bath shown in FIGS. 1 and 2. Therefore, description of the structure and function of the galvanizing bath constituting the general galvanizing apparatus will be omitted.

Figure 4 is a detailed view of the subject innovation, showing the configuration of the subject innovation shown in Figure 3 in more detail. The present invention can be largely divided into a rotating part, a driving part for rotating the rotating part, and a collecting part of the filtered top dross. Detailed configuration of each part will be described in detail with reference to FIGS. 4, 5, 6 and 7.

5 is a perspective view of a housing used in the present invention, FIG. 6 is a perspective view of a filtering member fixed to the housing, and FIG. 7 is a perspective view of a screw bar mounted in the housing.

In the hollow cylindrical housing 20 having both ends open, a plurality of longitudinal cutouts 21 are formed on the surface thereof, and the screw bar 40 illustrated in FIG. 7 is fixed therein. That is, a circular support 22 is positioned at the center of both ends of the housing 20, and a plurality of connecting legs 23 extending from the support 22 are fixed to the inner surface of the housing 20. The screw bar 40 is inserted into and fixed in the support 22 such that the screw bar 40 is positioned in the housing 20.

As shown in FIGS. 4 and 5, both ends 41, 42 of the screw bar 40 secured within the housing 20 are exposed outside the housing 20, of which the exposed screw bar 40 is exposed. Both ends 41 and 42 are respectively accommodated in bearing blocks 11 and 12 fixed on the opposing frames constituting the plating bath 10. As a result, the housing 20 is installed while crossing the plating bath 10.

The screw bar 40 is made of a rod member, and is divided into two ends 41 and 42 exposed to the outside of the housing 10 and a central portion 43 formed with the protruding spiral 44 as described above. Exposed both ends 41 and 42 are accommodated in the bearing blocks 11 and 12 mounted in the plating bath 10, respectively, and the height of the spiral 44 is the end of the spiral 44 on the inner surface of the housing 10. It is determined to be almost adjacent.

The driving unit 50 is mounted on the support provided on one side of the plating bath 10, and the driving shaft of the driving unit 50 and the exposed end 42 of the screw bar 40 described above are driven by a power transmission such as a belt or a gear. Connected to each other by means. Therefore, according to the operation of the driving unit 50, the screw bar 40 and the housing 20 to which the screw bar 40 is fixed rotate in the same manner.

The filtering members 30 as shown in FIG. 6 are respectively fixed to the plurality of cutouts 21 formed in the longitudinal direction on the surface of the housing 20. The filtering member 30 has a length slightly longer than the length of the cutout 21 of the housing 20, the cross section of which is semicircular. The filtering member 30 also has an empty space inside, but its bottom part 33 and the recessed part 31 (open face) are open over the entire length. A plurality of openings 35 are formed in the convex part 32 as shown in FIG. The filtering member 30 having such a configuration fixes the bottom both ends of the opening 21 of the housing 20 to both sides (21a and 21b of FIG. 5), so that the plurality of filtering members are formed as shown in FIG. 3. It is fixed to the surface.

On the other hand, the housing 20 mounted on the plating bath 10 does not contact the plating liquid contained in the plating bath 10, and only the filtering member 30 comes into contact with the plating liquid.

On the other side of the plating bath 10 in which the drive unit 50 is installed, the collecting unit 60 collecting the top dross is located. The collecting unit 60 may include a collecting box transferred along a first rail 61, a plate 62 conveyed along the first rail 61, and a second rail 63 horizontally disposed on the plate 62. 64).

Referring to the operation and function of the present invention as described above are as follows.

As described above, the driving unit 50 is used to remove the top dross formed on the liquid level of the plating liquid contained in the plating bath 10 by the oxidation reaction between the hot liquid zinc contained in the plating bath 10 and the cold air injected from the knife. ), The housing 20 and the screw bar 40 fixed therein rotate together. During the rotation of the housing 20, the filtering member 30 fixed to the surface of the housing 20 is gradually locked to the plating liquid. At this time, if any one of the filtering member 30 is located under the housing 20, that is, completely locked in the plating liquid, the top dross is introduced into the filtering member 30 through the open front portion 31 of the filtering member 30. The contained plating liquid flows in.

As the filtering member 30 is positioned above the housing 20 through the plating liquid according to the continuous rotation of the housing 20, the plating liquid contained in the filtering member 30 is transferred to the rear portion 32 of the filtering member 30. It is discharged to the outside through the formed plurality of openings 35 and flows back into the plating bath 10, but the top dross contained in the plating liquid does not pass through the openings 35 of the filtering member 30. When the filtering member 30 is positioned above the housing 20, the top dross is dropped into the housing 20 through the open bottom 33 of the filtering member 30.

The top dross dropped into the housing 20 is forcibly transferred to the end of the housing 20 by the screw bar 40 rotating together in the housing 20. As described above, since the end of the spiral 44 of the screw bar 40 is almost adjacent to the inner surface of the housing 20, all the top drosses positioned at the bottom of the housing 20 are the spirals 44 of the rotating screw bar 40. Is conveyed by).

The top dross conveyed to the end of the housing 20 is moved through the side opening of the housing 20 (specifically, the space between the legs 23 of the support 22) by the rotation of the screw bar 40. 20) Forced discharge to the outside, the discharged top dross is collected into a collection box 64 located outside the plating bath (10).

The discharge process of the top dross is sequentially performed in all the filtering members 30 mounted on the surface of the top dross according to the rotation of the housing 20. On the other hand, in the collecting unit 60, the collecting box 64 placed on the second rail 63 horizontally disposed on the plate 62 is moved left and right (drawing reference) by the cylinder 64a and collected as a top. It can be loaded uniformly in the box 64. When the top dross is filled in the collection box 64, the collection box 64 is transferred to the waste treatment plant along the first rail 61 by the operation of the driving unit 62a mounted on the plate 62, and then the top draw contained therein. The collection box 64 from which the scrub was removed is transferred again to proceed with the above-described process.

The present invention as described above can continuously remove the top dross formed on the surface of the plating liquid in the process of galvanizing the strip (strip) can improve the quality of the strip surface. In particular, the top dross removal process is automatically performed by the rotation of the housing and the screw bar according to the operation of the drive unit can be expected to the effect that can prevent the injury of the operator.

In the above description, for example, the present invention was applied to the galvanizing bath for proceeding the galvanizing process for the strip, but it can be applied to any process solution containing foreign matters.

Claims (2)

A hollow member having both ends open, the housing having a plurality of longitudinal cutouts formed on the surface thereof; Screw bars are fixed to the inner surface of the housing through a plurality of connecting legs at both ends of the housing, and both ends are exposed to the outside of the housing and are respectively accommodated in the bearing block fixed on the opposite frame of the process solution tank. A driving unit mounted on a support installed on one side of the process solution tank and connected to an exposed end of the screw bar to rotate the housing and the screw bar; A plurality of filtering members fixed to the surface of the housing so as to correspond to the plurality of cutouts formed on the surface of the housing to introduce only foreign substances contained in the process solution into the housing through the cutouts; The process solution-containing foreign matter removal device, characterized in that the drive unit is located on the other side of the process solution tank is installed to collect the foreign matter discharged to one end of the housing. The method of claim 1, Each of the filtering members has a semicircular cross section having an empty space therein, the bottom part and the front part of which are open over the entire length, and a plurality of openings are formed in the rear part of the process solution.