KR101264236B1 - Apparatus for automatic filtering of cooling water - Google Patents

Abstract

The present invention is connected to the cooler, the coolant is supplied from the cooler, and filtering the resin foreign material contained in the cooling water through a cylindrical mesh installed therein and then the coolant from which the resin foreign material is removed to the cooler A circulating connecting body portion; An automatic filtering unit disposed inside and outside the cylindrical mesh net and having a brush in contact with the cylindrical mesh net, and receiving washing water to remove the resin foreign matter attached to the cylindrical mesh net; And detecting a pressure of the cooling water supplied to the connection body unit, and if the pressure of the cooling water is greater than a preset pressure, cut off the supply of the cooling water flowing into the connection body unit, and supply the washing water to the automatic filtering unit, And a control unit for rotating the automatic filtering unit along the circumference of the cylindrical mesh network, wherein the automatic filtering unit converts the washing water into a vortex to rotate the brush, and moves the brush forward and backward to move the cylindrical mesh. It provides a cooling water automatic filtering device, characterized in that for removing the foreign matter attached to the net.
According to the present invention, by converting the washing water into the vortex form and by rotating the brush, and also vibrating the brush back and forth, it is possible to improve the efficiency of the debris removal operation and to extend the brush exchange cycle.

Description

Cooling water automatic filtering device {APPARATUS FOR AUTOMATIC FILTERING OF COOLING WATER}

The present invention relates to a cooling water automatic filtering device that filters the cooling water and removes the filtered resin foreign material, and more particularly, by converting the washing water into a vortex and rotating the brush, thereby vibrating the brush back and forth, The present invention relates to an automatic cooling water filtering device that can improve the efficiency of debris removal and extend the brush change interval.

In general, there are kinds of post-treatment resin coatings in steelworks plating process lines such as resin coatings for organic resins, organic resin coatings, resin coatings for fuel tanks that are metallic resin solutions, and black steel sheet resin coatings for LCD panels. To do this, the resin solution for each type is coated with resin on the top coater (2) and bottom coater (3). By the work, the resin coating work is completed.

Here, the production of resin coated steel sheets, such as anti-finger steel sheet, fuel tank steel sheet, black resin steel sheet, and the like after the resin primary solution is applied, the resin top coater (2), bottom after passing through the oven (4), cooler (5) and a dryer The coater 3 is coated with a resin solution of about 1000 to 5000 mg / m 2 by the rotational speed ratio of the coater roll and the nip (NIP) pressure, and then the strip 1 is dried by Auburn 4, which is an indirect heating method, and the cooler ( In 5) it is cooled. At this time, in the process of drying in the Auburn 4 and cooling in the cooler 5, the cooling water 6 of the cooler 5 is sprayed by a high pressure spray type, in this case, a resin of high temperature (150 ~ 250 degrees) Sudden spray cooling of the coated strip 1 results in a failure of the coated resin falling off at the strip angular portion at the edge of the strip 1. In addition, the resin-coated middle portion also little by little by the high-pressure spray of cooling water (6) is separated from the resin foreign particles, these foreign materials are buried in the wipe roll (10) while being circulated with the cooling water (6), The roll causes a defect in the form of surface defects such as the waterline mark 12. In addition, when a foreign material is severe, shape defects, such as the roll dent 11, generate | occur | produce.

In order to improve this problem, conventionally, a filter having a screen was installed to perform a circulating operation. In this case, too much foreign material was clogged so that the worker had to clean the filter manually by hand, and the above-mentioned quality defects occurred. There was a problem of cost loss and quality deterioration because it was not greatly improved.

The present invention has been made to solve the above-mentioned problems, by converting the washing water into the vortex form and by rotating the brush, and also by vibrating the brush before and after, to improve the efficiency of the debris removal work and brush exchange It is an object of the present invention to provide an automatic cooling water filtering device capable of extending the period.

The present invention is connected to the cooler, the coolant is supplied from the cooler, and filtering the resin foreign material contained in the cooling water through a cylindrical mesh installed therein and then the coolant from which the resin foreign material is removed to the cooler A circulating linking body portion; An automatic filtering unit disposed inside and outside the cylindrical mesh net and having a brush in contact with the cylindrical mesh net, and receiving washing water to remove the resin foreign matter attached to the cylindrical mesh net; And detecting a pressure of the cooling water supplied to the connection body unit, and if the pressure of the cooling water is greater than a preset pressure, cut off the supply of the cooling water flowing into the connection body unit, and supply the washing water to the automatic filtering unit, And a control unit for rotating the automatic filtering unit along the circumference of the cylindrical mesh network, wherein the automatic filtering unit converts the washing water into a vortex to rotate the brush, and moves the brush forward and backward to move the cylindrical mesh. It provides a cooling water automatic filtering device, characterized in that for removing the foreign matter attached to the net.

Here, the automatic filtering unit, a cylindrical housing connected in communication with the pipe for supplying the washing water, screw wire guiding for converting the washing water disposed in the cylindrical housing and supplied in the vortex form, in front of the screw wire guiding The propeller is disposed and rotated by the washing water converted into the vortex form by the screw wire guiding, and the brush is connected to the rotation axis of the propeller and the brush is formed on one side and rotates in conjunction with the rotation of the propeller It also has its features.

In addition, the automatic filtering unit, the brush housing coupled to the end of the cylindrical housing in front of the propeller and connected to the brush plate, the brush housing to change the position of the brush plate by moving back and forth by the pressure of the washing water in the vortex form There is also a feature to include more.

In this case, the brush housing is connected through the cylindrical housing and the rod shaft, the rod shaft penetrating through the brush housing and the cylindrical housing further protrudes toward the front of the brush housing, the spring is coupled to the protruding rod shaft, the brush housing There is also a feature to elastic support.

In addition, the connection body portion is connected to the filter lower body is connected to the cooler on one side is formed with an inlet main pipe for introducing the coolant, and the other side is formed with a discharge main pipe for discharging the coolant, and the filter lower body It is also characterized in that it includes a filter upper body for the installation space of the cylindrical mesh inside.

In addition, the filter upper body is connected to the backwashing supply pipe for supplying the wash water, the backwashing supply pipe is in communication with the pipe assembly for supplying the wash water to the automatic filtering unit, the pipe assembly is rotated by a motor There is also a feature.

According to the present invention, by converting the washing water into the vortex form and by rotating the brush, and also vibrating the brush back and forth, it is possible to improve the efficiency of the debris removal operation and to extend the brush exchange cycle.

In addition, according to the present invention, by performing a proper brush work until the brush is completely worn, it is possible to prevent the occurrence of defects such as roll dents, roll marks, etc. that occurred in the past, through which the process for a long time By being able to proceed, work efficiency can be improved more.

1 is a block diagram showing a resin process according to the prior art.
2 is a cross-sectional view showing an automatic cooling water filtering device according to the present invention.
3 is a cross-sectional view of the portion B shown in Figure 2 cut in the direction of the arrow.
4A is a detailed cross-sectional view of portion A of FIG. 2.
FIG. 4B is a detailed cross-sectional view of portion C of FIG. 2;
Figure 5a is a cross-sectional view showing a state of the automatic filtering portion in accordance with the present invention.
Figure 5b is a cross-sectional view showing a variable state of the automatic filtering unit according to the present invention.
Figure 6 is a block diagram showing a resin process having a cooling water automatic filtering device according to the present invention.

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

2 to 6, the automatic cooling water filtering device 100 according to the present invention is connected to the cooler 5 of the resin process to filter the foreign matter contained in the coolant 6 supplied from the cooler 5. Then, the device circulates the cooling water 6 from which the resin foreign material 7 has been removed to the cooler 5, and at the same time, effectively removes the resin foreign material 7 stuck to the cylindrical mesh net 37 in the filtering process. The automatic cooling water filtering device 100 is formed to include a connection body 110, an automatic filtering unit 120 and a control unit (not shown).

The connection body 110 forms a body of the automatic cooling water filtering device 100, is connected to the cooler 5, and accommodates the cylindrical mesh net 37 and the automatic filtering unit 120 inside. The connection body 110 is formed to include a filter lower body 35 and the filter upper body (39).

Here, an inlet main pipe 36 is formed at one side of the filter lower body 35 to connect the cooler 5 to introduce the coolant 6 pumped from the cooler 5, and the other side thereof corresponds to a cylindrical mesh net. A discharge main pipe 28 is formed to discharge the cooling water 6 filtered through the 37 to remove the foreign matter 7 and circulate back to the cooler 5. The discharge main pipe 28 is connected to the coolant return pipe (not shown) of the cooler 5. In addition, on the other side of the filter lower body 35, a backwashing drain pipe 33 for discharging the washing water used for washing the resin foreign matter 7 stuck to the cylindrical mesh net 37 is formed. The backwashing drain pipe 33 is connected to the waste water tank (not shown). At this time, the back washing drain pipe 33 is automatically installed to the drain automatic valve 34 is to control the washing water discharged, the operation of the drain automatic valve 34 is controlled through a controller (not shown).

In addition, a first bearing block housing 29 connected to a lower end of the second pipe 38 to be described later is installed inside the filter lower body 35, and the side of the first bearing block housing 29 is provided with a filter lower body ( And the inner wall of 35). In this case, a plurality of solution flow holes 31 are formed in the first bearing block housing 29, and preferably, four solution flow holes 31 are used to move the cooling water 6 or the washing water. In addition, a cylindrical mesh net 37 is connected to an upper side of the first bearing block housing 29, and the first bearing block housing 29 and the cylindrical mesh net 37 may be bolted.

On the other hand, the frame 32 is connected to the outer lower end of the filter lower body 35 is fixed to the bottom stably.

The upper filter body 39 is combined with the lower filter body 35 to form an installation space of the cylindrical mesh net 37 and the automatic filtering unit 120 therein. At this time, the filter upper body 39 and the filter lower body 35 may be bolted. The upper filter body 39 is open at the upper end and the second bearing block housing 19 is coupled to the open area. The third bearing block housing 17 is seated and bolted to the upper portion of the second bearing block housing 19, and the first bearing block cover 16 is seated to the upper part of the third bearing block housing 17. Combined. In addition, a motor bracket 46 is installed between the lower portion of the third bearing block housing 17 and the upper filter body 39. In addition, the gear block 14 is bolted to the upper portion of the third bearing block housing 17, the gear block 14 is connected to the motor (13). Here, the motor 13 rotates the automatic filtering unit 120 along the outer circumference of the cylindrical mesh net 37. The operation of the motor 13 will be described in more detail below.

Meanwhile, the gear block shaft 15 is connected to the gear block 14, and the gear block shaft 15 is disposed to penetrate through the centers of the first bearing block cover 16 and the third bearing block housing 17. At the end thereof, the coupling 18 is coupled. The other side of the coupling 18 to which the gear block shaft 15 is connected is connected to the inlet hole housing 20 through a pipe, and the inlet hole housing 20 is connected to the first pipe 21 constituting the pipe assembly. . At this time, the second bearing block cover 42 is bolted to the inner lower end of the second bearing block housing 19, the first pipe 21 is disposed through the center thereof.

Here, the inlet hole housing 20 is a passage for moving the supplied washing water to the first pipe 21. At this time, the washing water is introduced through the back washer supply pipe 45, this back washer supply pipe 45 is formed to communicate with the second bearing block housing 19 through the motor bracket (46). And the backwashing supply pipe 45 is connected to the washing water supply pipe (not shown) and receives the washing water therefrom. At this time, the presence or absence of supply of such washing water is made through the backwashing supply automatic valve 44 installed in the backwashing supply pipe 45, the backwashing supply automatic valve 44 is controlled through a controller (not shown) do.

Subsequently, the first pipe 21 is connected to the distribution connection pipe 41. The curved pipe 23 is connected to one distribution port of the distribution connection pipe 41, and the second pipe 38 is formed in the same line as the first pipe 21 at the other distribution port. In this case, a plurality of inner spray pipes 26 are connected to the second pipe 38 along the longitudinal direction, and the inner spray pipes 26 are disposed inside the cylindrical mesh net 37 of the automatic filtering unit 120. The parts are connected. In addition, a plurality of outer spray pipes 27 are connected to the curved pipe 23 along the length direction, and the outer spray pipe 27 has a portion disposed outside the cylindrical mesh net 37 of the automatic filtering unit 120. Connected. Here, it is preferable that the plurality of inner spray pipes 26 and the outer spray pipes 27 are formed to correspond to each other via a cylindrical mesh.

Meanwhile, a pipe bracket 24 is fixedly connected to the second pipe 38 and the plurality of inner spray pipes 26, and the lower end of the second pipe 38 passes through the center of the third bearing block cover 30. It is connected to the first bearing block housing (29). At this time, the first bearing block housing 29 and the third bearing block cover 30 are bolted, the upper end of the cylindrical mesh net 37 bolted to the bottom of the upper end of the first bearing block housing 29 The fourth bearing block housing 40 is bolted. The fourth bearing block cover 22 is bolted to an upper portion of the fourth bearing block housing 40. Accordingly, the second pipe 38 is connected through the center of the fourth bearing block cover 22 and the fourth bearing block housing 40 in turn.

The automatic filtering unit 120 is a device for removing the resin foreign material 7 attached to the cylindrical mesh net 37 by receiving the washing water, and the inner and outer sides of the cylindrical mesh net 37 among the inner side of the connecting body unit 110. Is placed on. The automatic filtering unit 120 is formed to include a cylindrical housing 48, screw wire guiding 47, a propeller 60 and a brush plate 54.

Here, the cylindrical housing 48 is installed in the plurality of inner and outer spray pipes 26 and 27 for supplying the washing water, respectively. The screw wire guiding 47 is disposed inside the cylindrical housing 48 and converts the washing water supplied through the spray pipes 26 and 27 into the vortex form. In addition, the propeller 60 is disposed in front of the screw wire guiding 47 and is rotated by the washing water converted into a vortex by the screw wire guiding 47. And the brush plate 54 is connected to the axis of rotation of the propeller 60, the brush 55 is formed on one side, that is, the surface facing the cylindrical mesh net 37, the rotation of the propeller 60 By rotating in a circular according to the brush 55 to remove the foreign matter 7 attached to the cylindrical mesh net 37.

Meanwhile, the brush housing 53 may be coupled to an end portion of the cylindrical housing 48 in front of the propeller 60. The brush housing 53 is connected to the brush plate 54 via the rotation shaft 58 of the propeller 60. The brush housing 53 is formed to move back and forth by the pressure of the washing water, the movement of the brush housing 53 is transmitted to the brush plate 54, the blush plate 54 and the brush housing 53 and They move in the same direction. As such, when the brush housing 53 and the brush plate 54 move back and forth, even when the brush 55 is worn, the brush housing 53 can be pressed against the cylindrical mesh net 37 to extend the brush 55 replacement cycle. The removal efficiency of the foreign material 7 can be further increased.

Here, the movement of the brush housing 53 may be implemented through the spring 51. That is, the brush housing 53 and the cylindrical housing 48 are coupled to the plurality of rod shafts 50 through the side periphery thereof, wherein the rod shafts 50 are formed to protrude further toward the front of the brush housing 53. . And the spring 51 is coupled to the protruding portion of the rod shaft 50 in this way to elastically support the brush housing 53, through which, when the pressure of the washing water is applied to the brush housing 53, before and after moving do. In addition, in order to fix the columnar rod shaft 50 and prevent the spring 51 from being separated, a ring plate 52 is provided at one end of the rod shaft 50, that is, at the end of the side to which the spring 51 is coupled. Is coupled and the limiter 49 is coupled to the other end, that is, the end of the cylindrical housing 48 side.

In addition, when the coupling relationship to the above components will be described in more detail, the brush plate 54 is connected to the brush shaft 56. And the brush shaft 56 is connected to the brush shaft coupling 57, which is connected to the rotary shaft 58 of the propeller 60, the rotary shaft 58 is fitted into the propeller bearing block 59 is penetrated through. . In addition, one end of the rotary shaft 58 is connected to the propeller 60, the propeller bearing block 59 is fitted to the center of the penetration flat ring (63). At this time, the penetration plate ring 63 is formed with a plurality of penetration holes 63. The penetration plate ring 63 is fitted to the brush housing 53. And the cylindrical housing 48 is connected to the pipe coupling 61, this pipe coupling 61 connects the inner and outer spray pipes 26 and 27 and the cylindrical housing 48 to each other.

The controller (not shown) controls the cooling of the cooling water 6 and the process of removing the foreign matter 7. That is, the controller (not shown) detects the pressure of the cooling water 6 supplied to the connection body 110, and at this time, if the pressure of the cooling water 6 is greater than or equal to the preset pressure, the controller flows into the connection body 110. Supply of the cooling water 6 to be cut off. In addition, the controller (not shown) supplies the washing water to the automatic filtering unit 120 while the supply of the cooling water 6 is blocked, and simultaneously operates the motor 13 to supply the automatic filtering unit 120 to the cylindrical mesh network 37. Rotates along the inner and outer circumferences.

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

First, the cooling water 6 is filtered, when the cooling water 6 of the cooler 5 is introduced into the connection body 110 through the inlet main pipe 36 by a pumping action, the cooling water 6 is a solution flow hole. Through the 31 is introduced into the cylindrical mesh net 37, at this time, the resin foreign material 7 contained in the cooling water 6 is filtered by the cylindrical mesh net 37, and passes through the cylindrical mesh net 37 One clean coolant (6) is discharged through the discharge main pipe (28), and the discharged coolant (6) is returned to the cooler (5) through a coolant return pipe (not shown) connected to the discharge main pipe (28). Will move. Here, the cooling water 6 filtering process is continuously repeated.

As such, the proper pressure is applied to a pressure gauge (not shown) installed in the coolant return pipe (not shown) through which the coolant 6 discharged from the coolant automatic filtering device 100 passes while the filtering process for the coolant 6 is performed. When the abnormality is detected, the controller (not shown) converts the cooling water 6 filtering process of the automatic cooling water filtering device 100 to the resin foreign material 7 removing process.

That is, through the control of the controller (not shown), first, the operation of the pump for supplying the coolant 6 to the inlet main pipe 36 is stopped, and an automatic valve (not shown) connected to the inlet main pipe 36 is It will be cut off. In addition, the automatic valve (not shown) connected to the discharge main pipe 28 is also blocked.

Next, the motor 13 is activated, in which case the motor 13 can be set to a timer to operate for approximately 3 minutes.

Next, with the operation of the motor 13, the drain automatic valve 34 is opened to discharge the coolant 6 inside the connection body 110 to the waste water tank (not shown), and at the same time, the backwashing supply automatic valve. 44 is opened to supply the washing water to the automatic filtering unit 120 through the backwashing supply pipe 45. At this time, the washing water supplied through the backwashing supply pipe 45 is supplied to the plurality of spray pipes 26 and 27 in a high pressure state.

Next, the high pressure washing water is converted into a vortex by the screw wire guiding 47, and the vortex washing water rotates the propeller 60 by spray contact with the propeller 60.

Next, the brush plate 54 and the brush 55 connected thereto by the rotational action of the propeller 60 rotate about the magnetic axis, and the resin foreign material adhering to the cylindrical mesh net 37 through such rotation. (7) is removed. Here, even when the length of the resin shortening is shortened due to abrasion of the brush 55 while the resin foreign material 7 is being removed, the brush housing 53 is elasticated by the spring 51 by the pressure of the vortex type washing water. Through the bearing force, the positional movement in the forward and backward directions is buffered. In other words, the brush housing 53 vibrates in the front and rear directions. And through this, it is possible to continue to remove the foreign matter (7) until the brush 55 is completely worn, it is possible to prevent frequent brush 55 replacement work.

On the other hand, by the operation of the motor 13 at the same time as the brush operation by the washing water as described above, the second pipe 38, the curved pipe 23 connected to it is rotated around the cylindrical mesh net 37, accordingly In addition, the automatic filtering unit 120 connected to the pipes 38 and 23 also rotates along the inner and outer circumferences of the cylindrical mesh net 37, so that the foreign matter 7 on the entire cylindrical mesh net 37 is formed. The removal process can be performed.

In addition, the debris 7 and the washing water separated by the debris 7 removal process are discharged to the waste water tank (not shown) through the backwashing drain pipe 33.

After approximately 3 minutes have elapsed, the motor 13 is stopped, and the controller (not shown) applies the cooling water 6 again to control the cooling water 6 filtering process.

One; Strip 2; Top coater 3; Bottom coater
4; Auburn 5; Cooler 6; cooling water
7; Foreign material 8; Circulating pump motor 9; Cooling water supply valve
10; Wiper roll 11; Roll dent 12; Roll line mark
13; Motor 14; Gear block 15; Gear block shaft
16; First bearing block cover 17; Third bearing block housing 18; Coupling
19; Second bearing block housing 20; Inlet hole housing 21; First pipe
22; Fourth bearing block cover 23; Curved pipe 24; Piping Bracket
26; Inner spray pipe 27; Outer spray pipe 28; Exhaust main piping
29; First bearing block housing 30; Third bearing block cover 31; Solution flow hole
32; Frame 33; Backwashing drain piping 34; Drain automatic valve
35; Filter lower body 36; Incoming pipeline 37; Cylindrical Mesh
38; Second pipe 39; Filter upper body 40; 4th bearing block housing
41; Distribution connection pipe 42; Second bearing block cover 44; Back Washing Supply Auto Valve
45; Backwashing supply piping 46; Motor bracket 47; Screw Wire Guiding
48; Cylindrical housing 49; Limiter 50; Shrink
51; Spring 52; Ringplate 53; Brush housing
54; Brushplate 55; Brush 56; Brush axis
57; Brush shaft coupling 58; Axis of rotation 59; Propeller Bearing Block
60; Propeller 61; Pipe coupling 63; Feed Flat Ring
64; Through hole 110; Connection body 120; Auto Filtering Part
100; Cooling water automatic filtering device

Claims (6)

A connection connected to a cooler, receiving coolant from the cooler, filtering a foreign material contained in the cooling water through a cylindrical mesh network installed therein, and then circulating the coolant from which the foreign material has been removed to the cooler Body portion;
An automatic filtering unit disposed inside and outside the cylindrical mesh net and having a brush in contact with the cylindrical mesh net, and receiving washing water to remove the resin foreign matter attached to the cylindrical mesh net; And
Sensing the pressure of the cooling water supplied to the connection body unit, and if the pressure of the cooling water is greater than a preset pressure, the supply of the cooling water to the connection body unit is cut off, and the washing water is supplied to the automatic filtering unit, It includes a control unit for rotating the automatic filtering unit along the circumference of the cylindrical mesh,
The automatic filtering unit rotates the brush by converting the wash water into a vortex, and moves the brush in the forward and backward directions to remove the foreign matter attached to the cylindrical mesh net.
Cylindrical housing connected in communication with the pipe for supplying the wash water,
Screw wire guiding for converting the wash water disposed in the cylindrical housing and supplied into the vortex form,
A propeller disposed in front of the screw wire guiding and rotating by the washing water converted into a vortex by the screw wire guiding, and
Cooling water automatic filtering device characterized in that it comprises a brush plate connected to the rotating shaft of the propeller and the brush is formed on one side and rotates in conjunction with the rotation of the propeller.
delete The method of claim 1,
The automatic filtering unit,
And a brush housing coupled to the cylindrical housing end in front of the propeller and connected to the brush plate and varying the position of the brush plate by moving forward and backward by the pressure of the washing water in the vortex form. Cooling water automatic filtering device.
The method of claim 3,
The brush housing is connected through the cylindrical housing and the rod shaft,
The rod shaft penetratingly coupled to the brush housing and the cylindrical housing further protrudes toward the front of the brush housing, and a spring is coupled to the protruding rod shaft to elastically support the brush housing.
The method of claim 1,
The connecting body portion,
An inlet main pipe connected to the cooler to introduce the coolant to one side thereof, and a filter lower body to which an exhaust main pipe to discharge the coolant is formed to the other side thereof;
Cooling water automatic filtering device comprising a filter upper body coupled to the filter lower body to the installation space of the cylindrical mesh inside.
The method of claim 5,
The filter upper body is connected to the back washer supply pipe for supplying the wash water, the back washer supply pipe is in communication with the pipe assembly for supplying the washing water to the automatic filtering unit, the pipe assembly is characterized in that the rotating by the motor Cooling water automatic filtering device.

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