KR102478154B1 - Manufacturing apparatus for ingot - Google Patents

Abstract

The present invention relates to an automatic ingot manufacturing apparatus, and more specifically, to an automatic ingot manufacturing apparatus capable of increasing the cooling speed of molten brass in an ingot tray so as to innovatively reduce the manufacturing time, thereby expecting higher productivity. The automatic ingot manufacturing apparatus comprises a melter for melting brass, a conveyor for moving a plurality of ingot trays containing the melt discharged from the melter, and a cooler for cooling the melt contained in the ingot trays on the path of the conveyor.

Description

Ingot automatic equipment {Manufacturing apparatus for ingot}

The present invention relates to an automatic ingot equipment, and more particularly, to an automatic ingot equipment that can significantly reduce manufacturing time by cooling a molten brass melt more rapidly in an ingot tray, thereby expecting higher productivity. will be.

Brass is a copper-zinc (Cu-Zn) binary alloy, to which alloy elements are added depending on its use. It is used in machinery, electricity/electronics, automobiles, construction, other drinking water-related distribution system parts, and daily necessities. It is a capital good for industrial foundations widely used across all industrial fields.

Such brass can be supplied in various forms of ingots depending on the purpose of use. In the manufacture of brass ingots, first, a certain amount of brass melt melted in a melting furnace is injected into an ingot mold (hereinafter referred to as an ingot tray), and appropriately cooled It can be manufactured by demolding the cured ingot from the ingot tray.

On the other hand, it is common that a cooling means for cooling the brass ingot is installed in the brass ingot manufacturing process line.

The temperature of the brass melted in the melting furnace turns around 900 ° C, and even if this melt is injected into the ingot tray, the temperature does not easily drop during air cooling, so that the brass ingot is not forcibly cooled in the manufacturing line. If it does, it is obvious that productivity cannot be guaranteed.

In addition, if the brass ingot is not cooled in an appropriate way, the temperature difference between the inside and outside of the ingot becomes larger, and damage and cracks occur due to deterioration of physical properties, and serious defects such as forging, molding, and free cutting are caused. Due to the deterioration of the properties of the material, the above-described various problems are included.

Patent Publication 10-2020-0080203

The present invention was created to solve this in view of the various problems in the prior art, and by cooling the molten brass melt more rapidly in the ingot tray to dramatically shorten the manufacturing time, an automatic ingot facility that allows higher productivity to be expected Its purpose is to provide a device.

The present invention is a means for achieving the above object, which is installed on a melter for melting brass, a mover for moving a plurality of ingot trays containing melt discharged from the melter in a row, and a path of the mover, the ingot An automatic ingot equipment device including a cooler for cooling melt contained in a tray, wherein the cooler includes: a cooling water chamber disposed under the mover and storing cooling water; a spraying device disposed above the mover and connected to the coolant chamber to spray the coolant stored in the coolant chamber to the top of the mover; and a purifier disposed directly below the mover, connected to the coolant chamber, and recovering the coolant injected into the mover, purifying it, and returning it to the coolant chamber.

In addition, the purifier may include a collection hopper unit fixedly installed directly below the moving machine to recover the cooling water falling from the moving machine; a purification unit consisting of a pair of two sets, at least one of which is selectively connected to an upper portion of the cooling water chamber to receive cooling water, and a purification filter built-in to filter the cooling water; a washing unit disposed at one side of the cooling water chamber and connected to a purifying unit not connected to the cooling water chamber among the pair of purifying units to clean the purifying unit; and a moving unit that supports the pair of purifiers apart and rotates the purifiers to the position of the cooling water chamber or the washing unit so that each purifying unit is alternatively connected to the cooling water chamber and the cleaning unit.

In addition, each of the pair of purifying units includes a housing having a cylindrical shape containing the purifying filter, and having an upper and lower connectors extending from upper and lower ends, respectively; and a diffusion member fixedly installed on the upper part of the purifying filter inside the housing and diffusing and supplying the coolant flowing into the housing toward the purifying filter, wherein the moving part is formed in a plate shape and is located at the upper part of each of the pair of housings. An upper support plate through which a pair of upper fixing holes into which connectors are inserted is formed to support an upper end of the housing; a lower support plate spaced downward in parallel with the upper support plate, formed in the form of a plate, and having a pair of lower fixing holes through which the lower connectors of the pair of housings are inserted to support the lower end of the housing; an interlocking shaft coupled through the center of the upper support plate and the lower support plate and interlocking the upper support plate and the lower support plate; and a driving motor for rotationally driving the interlocking shaft, wherein when the upper support plate and the lower support plate rotate in a synchronous direction according to the rotation of the interlocking shaft, the cooling water chamber and the purifier connected to the washer are rotated and moved to exchange positions with each other. characterized by

In addition, the injection device may include a vertical pipe extending upwardly in a state directly connected to the cooling water chamber; a first circulation pump installed in the vertical pipe to pump the cooling water stored in the cooling water chamber to the vertical pipe; and a horizontal pipe branching from the vertical pipe and extending to the upper part of the mover, in which a plurality of spray nozzles are coupled and installed along the longitudinal direction, wherein the washing part stores washing water and has a lower connector of the housing at the upper end. a washing water chamber in which a washing water recovery port is formed; a washing water pipe that is directly connected to the washing water chamber and extends directly above the upper support plate and has a washing water outlet connected to the upper connector of the housing at an end thereof; a second circulation pump installed in the washing water pipe and pumping the washing water stored in the washing water chamber to the washing water pipe; and a washing water filtration filter installed on the conduit of the washing water pipe and filtering the washing water moving through the washing water pipe, wherein bearings are interposed between the upper connector and the upper fixing hole and between the lower connector and the lower fixing hole, The purification unit is configured to be relatively rotatable on the upper support plate and the lower support plate, and is installed adjacent to the purification unit connected to the washing unit to rotate the purification unit supported between the upper support plate and the lower support plate in place to centrifuge the foreign substances collected in the purification filter and a centrifugal separation unit for performing a centrifugal separator, wherein a belt-shaped silicon pad is formed on a circumferential surface of the housing, and the centrifugal separator includes: a drum forming a contact with the silicon pad; and a centrifugal motor for rotationally driving the drum so that the housing rotates in place.

In addition, the cooler may further include a vapor treatment device that is fixedly installed above the injection device and sucks in vapor generated by the injection of the cooling water and discharges it toward the mover.

The present invention provides an advantageous effect of allowing higher productivity to be expected by dramatically shortening the manufacturing time by cooling the molten brass melt more rapidly in the ingot tray.

1 is a view showing the overall configuration of an automatic ingot equipment according to the present invention.
Figure 2 is a view schematically showing the main part cross-sectional configuration of the present invention.
3 is a view showing a coupling configuration of a purification unit and a moving unit;
4 is a view showing an exploded configuration of a purification unit and a moving unit;
7 is an enlarged view of a cross-sectional configuration around a purification unit connected to a cooling water chamber;
6 is an enlarged view of a cross-sectional configuration around a purification unit connected to a washing unit;
7 is a view showing a rotational action of a purifier with respect to a plane;

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the examples described in detail below. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shapes of elements in the drawings may be exaggerated to emphasize a clearer explanation. It should be noted that in each drawing, the same members are sometimes indicated by the same reference numerals. Detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention are omitted.

As shown in FIG. 1, the automatic ingot equipment according to the present invention has a melter 1 for melting brass and a plurality of ingot trays 2 containing melt discharged from the melter 1 in a row. It can be defined as including a mover 3 for moving and a cooler 4 installed on the path of the mover 3 and cooling the melt contained in the ingot tray 2.

The melter (1) has an inlet where the brass to be melted is introduced, and a heating means is provided to completely melt the input brass by heating it to 900 ~ 1000 ℃, and the molten material melted in the melter (1) ) may be discharged to the outside through a discharge dispenser configuration provided.

The mover 3 may be exemplified by a conventional conveyor structure, and may be fixedly installed directly below the melter 1 to repeatedly move and stop the plurality of ingot trays 2.

Each ingot tray 2 may be provided with an ingot forming groove (not shown), and the melt discharged from the melter 1 may be injected into the ingot forming groove.

The brass ingot taken out after the melt is cooled in the ingot tray 2 may have an embossed shape of the ingot forming groove.

When the melt is cooled in the ingot tray 2, it may be taken out on the ingot tray 2 through an ejector (not shown).

The melting machine 1, the moving machine 3, the ingot tray 2, the take-out machine, etc. follow the structure of a known metal ingot manufacturing apparatus, so a detailed description thereof will be omitted, and the main features of the cooler 4 of the present invention are Therefore, the cooler 4 will be described in detail with reference to the accompanying drawings.

The cooler 4 rapidly cools the melt injected into the ingot tray 2 in a water-cooled manner so that the ingot can be taken out more quickly from the ingot tray 2 to ensure productivity. In particular, the cooling water directly contacts the melt to While maximizing the cooling efficiency, it has an advantageous structure to purify and circulate the foreign substances contained in the cooling water in a situation where various foreign substances are mixed in the cooling water during this process.

To this end, the cooler 4 may be exemplified as including a cooling water chamber 10 , an injection device 20 and a purifier 30 .

First, the cooling water chamber 10 is disposed below the mover 3, and the coolant is stored, and the coolant stored in the coolant chamber 10 is directly injected toward the mover 3 through the injection device 20. and can come into contact with the moving ingot tray 2 through the mover 3, and the cooling water that has exchanged heat with the melt can fall freely to the bottom of the mover 3 and return to the cooling water chamber 10 again.

That is, the cooling water stored in the cooling water chamber 10 is supplied to the injection device 20 and then sprayed, and the cooling water used for cooling returns to the cooling water chamber 10 to form a circulation structure.

A cooling water recovery hole 11 may be formed at an upper end of the cooling water chamber 10, and a purification device 30 is connected to the cooling water recovery hole 11 so that the cooling water falling from the direction of the purification device 30 is returned to the cooling water chamber. (10).

Although not shown, a chiller is coupled to the cooling water chamber 10 to operate by lowering the cooling water to an appropriate temperature, and normal water may be used as the cooling water used in the cooler 4 .

Next, the purifier 30 is disposed directly below the mover 3, is installed in connection with the cooling water chamber 10, collects and purifies the cooling water injected into the mover 3, and then moves the cooling water chamber It plays a role in returning to (10).

When the cooling water is directly injected into the melt, the oxide film or small chips formed on the surface of the brass ingot may be removed and mixed into the cooling water. In addition, there is a possibility that various foreign substances may be mixed into the inside of the brass ingot, which causes deterioration of the marketability of the finished ingot product.

Therefore, the purification device 30 purifies and circulates various impurities included in the cooling water by itself.

To this end, the purifier 30 is fixedly installed directly below the mover 3 and consists of a collection hopper unit 100 for recovering the cooling water falling from the mover 3, and a pair of two sets, at least one of which is A purification unit 200 that is selectively connected to the upper part of the cooling water chamber 10 to receive cooling water and has a built-in purification filter 210 to filter and process the cooling water. The cleaning part 300 connected to the purifying part 200 that is not connected to the cooling water chamber 10 among the pair of purifying parts 200 to clean the purifying part 200 and the pair of purifying parts 200 are spaced apart. Supporting and rotationally moving the purifying part 200 to the position of the cooling water chamber 10 or the washing part 300 so that each purifying part 200 is alternatively connected to the cooling water chamber 10 and the washing part 300 It may be illustrated as including part 400 .

First, the purifying unit 200 is configured to provide a space for purifying cooling water, and the pair of purifying units 200 may be connected to the cooling water chamber 10 or the cleaning unit 300, respectively.

That is, at least one of the pair of purification units 200 in the two sets is selectively connected between the recovery hopper unit 100 and the upper part of the cooling water chamber 10 to purify the cooling water, and the other one is a washing unit. It is connected to 300 and is a structure in which the inside including the purification filter 210 can be washed.

More specifically, each of the pair of purifying parts 200 is made of a cylindrical shape containing the purifying filter 210, and the upper and lower ends of the housing in which the upper connector 221 and the lower connector 222 are extended, respectively ( 220) and a diffusion member 230 fixedly installed on the upper part of the purification filter 210 inside the housing 220 and diffusing and supplying the cooling water introduced into the housing 220 toward the purification filter 210. can be exemplified.

The upper connector 221 and the lower connector 222 are made of a pipe structure having a diameter smaller than the maximum diameter of the housing 220 at the upper and lower portions of the housing 220, respectively, so that the housing 220 has a Venturi tube-type structure make it possible to have

Depending on the location of the purification unit 200, the upper connector 221 is connected to at least one of the recovery hopper unit 100 and the washing unit 300, and the lower connector 222 connects the cooling water chamber 10 and the washing unit. It may be connected to at least one of (300).

The diffusion member 230 may have a plate-like structure in which a plurality of diffusion holes 231 are perforated, and the cooling water or washing water introduced into the housing 220 is widely diffused so that the water can be uniformly dripped onto the purification filter 210. do.

The purification filter 210 serves to collect and process foreign substances contained in the cooling water, and the filtered substances collected on the purification filter 210 remain in the purification filter 210 or fall freely together with the cooling water into the cooling water chamber. It can be recovered by (10).

The pair of purifiers 200 have the same structure and are moved in parallel at a certain distance from each other and are supported by a moving part 400 to be described later, and are attached to either the cooling water chamber 10 or the washing part 300. An optional connection can be made.

That is, the cooling water passes through the purifying unit 200 coupled above the cooling water chamber 10 and is re-supplied to the cooling water chamber 10, and in this process, the cooling water is purified, and the washing unit 300 The connected purification unit 200 can be cleaned, and details related to the cleaning unit 300 will be described later.

Next, the injection device 20 is disposed above the mover 3 and is connected to the coolant chamber 10 to inject the coolant stored in the coolant chamber 10 to the top of the mover 3. do.

The injection device 20 is, for example, a vertical pipe 21 that extends upward while being directly connected to the cooling water chamber 10 and is installed in the vertical pipe 21 to discharge the cooling water stored in the cooling water chamber 10 vertically. It is branched from the first circulation pump 22 and the vertical pipe 21 that pressurize the pipe 21 and extends to the top of the mover 3, and a plurality of spray nozzles 24 are coupled and installed along the longitudinal direction. It can be illustrated as including a horizontal pipe 23 that is.

At this time, the cooling water chamber 10 and the recovery hopper unit 100 are located on the same line in a state of being spaced apart at regular intervals vertically, and form a space in which the purification unit 200 can be disposed. In particular, the cooling water chamber In the case of (10), it is supported on the ground, and in the case of the recovery hopper unit 100, it can be fixedly installed in the lower part of the mover 3 through a separate support bracket (not shown).

On the other hand, the cooling water pumped by the first circulation pump 22 through the horizontal pipe 23 can be sprayed directly above the mover 3 through the spray nozzle 24, and the sprayed cooling water cools the melt. After performing this, they fall into the recovery hopper unit 100, and then fall into the diffusion member 230 through the upper connector 221 of the housing 220.

Next, the moving unit 400 is a core component of the purifying device 30, and is disposed between the cooling water chamber 10 and the washing unit 300 to support the pair of purifying units 200 at a distance, and each purifying unit 200 serves to rotate and move the purifying unit 200 to the position of the cooling water chamber 10 or the washing unit 300 so that it is alternatively connected to the cooling water chamber 10 and the washing unit 300 .

That is, the pair of purifiers 200 have a structure capable of being exchanged between the cooling water chamber 10 and the recovery hopper 100 or the washing unit 300 as needed through the moving unit 400, especially In the cleaning process of the purifying unit 200, continuous cooling of the melt and purification of the cooling water without the need to specifically stop the purifying process of the purifying unit 200 connected between the cooling water chamber 10 and the recovery hopper unit 100. will be able to perform

More specifically, the moving unit 400 may be largely exemplified as including an upper support plate 410, a lower support plate 420, an interlocking shaft 430, and a driving motor 440.

The upper support plate 410 and the lower support plate 420 support the upper and lower ends of the housing 220, respectively, and have the same structure.

For example, the upper support plate 410 is formed in the form of a plate, and a pair of upper fixing holes 411 into which the upper connectors 221 of each of the pair of housings 220 are inserted are formed to penetrate the top of the housing 220. play a supporting role.

Each upper fixing hole 411 may be formed at an eccentric point at the same distance from the center of the upper support plate 410 in opposite outer directions.

At this time, in a state in which the upper connector 221 is inserted into the upper fixing hole 411, the upper connector 221 is not shielded by the upper support plate 410.

When the upper fixing hole 411 is exemplified in the form of a circular hole, the inner diameter of the upper fixing hole 411 is larger than the outer diameter of the upper connector 221, between the upper fixing hole 411 and the upper connector 221. so that the bearing (b) can be interposed therein.

Next, the lower support plate 420 is spaced downward in parallel with the upper support plate 410, and is formed in the form of a plate and is fixed to a pair of lower connectors 222 of each of the pair of housings 220 are inserted. The hole 421 is formed through and serves to support the lower end of the housing 220 .

At this time, each lower fixing hole 421 may be formed on the same line as the upper fixing hole 411, and similarly, when the lower fixing hole 421 is illustrated as a circular hole, the lower fixing hole 421 The inner diameter of ) is larger than the outer diameter of the lower connector 222 so that the bearing (b) can be interposed between the lower fixing hole 421 and the lower connector 222.

As such, the bearing (b) is interposed between the upper connector 221 and the upper fixing hole 411 and between the lower connector 222 and the lower fixing hole 421, so that the purifier 200 is connected to the upper support plate 410. And a structure that enables relative rotation on the lower support plate 420 is provided. The in-situ rotation of the purification unit 200 will be described together in the description of the centrifugal separation unit 40 to be described later.

Again, the interlocking shaft 430 passes through the center of the upper support plate 410 and the lower support plate 420 and is coupled to interlock the upper support plate 410 and the lower support plate 420. Rotational driving is performed by the motor 440 .

Accordingly, when the upper support plate 410 and the lower support plate 420 rotate in the synchronous direction, the coolant chamber 10 and the purifier 200 respectively connected to the washer 300 are rotated and moved so that their positions are exchanged. It is a structure that becomes

That is, as the interlocking shaft 430 rotates 180 degrees, the purifier 200 connected to the cooling water chamber 10 moves toward the cleaning unit 300, and the purifying unit 200 connected to the cleaning unit 300 moves toward the cooling water chamber. While rotating toward (10), the purifier 200 moved to the cooling water chamber 10 purifies the cooling water, and the purifier 200 moved to the washing unit 300 is contaminated, It can be washed by the cleaning unit 300 .

Next, the washing unit 300 cleans the inside of the housing 220 using a water treatment method so that the purification filter 210 containing the filtration material or the inner wall of the housing 220 can be restored to a clean state.

More specifically, the washing unit 300 includes a washing water chamber 310 in which washing water is stored and a washing water recovery hole 311 connected to the lower connection hole 222 of the housing 220 is formed at the upper end, the washing water chamber 310 The washing water pipe 320, which extends directly above the upper support plate 410 and has a washing water outlet 321 connected to the upper connector 221 of the housing 220 at the end, the washing water pipe ( 320) installed on the second circulation pump 330 for pressurizing the washing water stored in the washing water chamber 310 to the washing water pipe 320 and installed on the duct of the washing water pipe 320 and It may be exemplified as including a washing water filtration filter 340 for filtering the moving washing water.

At this time, the washing water chamber 310 and the washing water outlet 321 are located on the same line in a state of being spaced apart at regular intervals vertically, forming a space in which the purification unit 200, which has moved to the washing unit 300, can be disposed therebetween. will do

The washing water stored in the washing water chamber 310 is pumped by the second circulation pump 330 and moves to the upper end of the washing water pipe 320, that is, the washing water outlet 321, and then the upper connector connected to the washing water outlet 321 ( 221), washing water may be supplied into the housing 220.

At this time, although not shown, a nozzle may be formed in the washing water outlet 321 so that the washing water can be sprayed with a stronger pressure.

In particular, the washing water sprayed into the housing 220 falls into the diffusion member 230, and some of the washing water that has fallen into the diffusion member 230 falls toward the purification filter 210, and some of it falls toward the centrifugal separator (to be described later) By the action of 40), it is diffused to the inner wall surface of the housing 220 to clean the inner wall surface of the housing 220.

Washing water washing the inner wall of the purification filter 210 and the housing 220 falls freely due to its own weight and returns to the washing water chamber 310 through the washing water collection port 311 connected to the lower connector 222, The user should have a structure that minimizes unnecessary consumption of the washing water by appropriately replacing the washing water in consideration of the degree of contamination of the washing water.

Next, the centrifugal separation unit 40 is installed adjacent to the purification unit 200 connected to the washing unit 300 and rotates the purification unit 200 supported between the upper support plate 410 and the lower support plate 420 in place. It is responsible for centrifuging the foreign substances collected in the purification filter 210.

When the purification unit 200 connected to the cleaning unit 300 is rotated in place, foreign substances collected in the purification filter 210 are centrifuged out of the housing 220 by centrifugal force, while the purification unit 200 is rotated. If washing water is supplied in the meantime, the falling washing water can diffuse toward the inner wall surface of the housing 220 after colliding with the diffusion member 230 .

Accordingly, the centrifuged foreign matter is configured in close contact with the inner wall surface of the housing 220, and at this time, the washing water diffused to the inner wall surface of the housing 220 flows on the inner wall surface of the housing 220 to remove the centrifuged foreign matter. be able to

Accordingly, the centrifugal separation unit 40 appropriately rotates the purification unit 200 so that foreign substances collected in the purification unit 200 and the inner wall surface of the housing 220 can be effectively cleaned.

For this purpose, the centrifugal separation unit 40 includes, for example, a drum 41 forming a contact with the housing 220 and a centrifugal separation motor 42 that rotationally drives the drum 41 so that the housing 220 rotates in place. It can be exemplified by including. At this time, the centrifugal motor 42 can be fixedly installed on the washing water pipe 320.

In addition, a band-shaped silicon pad 223 is formed on the circumferential surface of the housing 220 so that the housing 220 can more intuitively interlock with the drum 41 when contact occurs between the housing 220 and the drum 41. The drum 41 forms a contact with the silicon pad 223 to provide stronger frictional force between the housing 220 and the drum 41 to minimize slip generation.

Although not shown, O-rings may be provided in the washing water outlet 321 and the washing water recovery hole 311 to prevent the outflow of the washing water when connected to the purification unit 200, and in some cases, drain the washing water leaked to the outside. It is indicated that drainage facilities may be provided for this purpose.

On the other hand, the cooler 4 may further include a vapor treatment device 50 for sucking in vapor generated by cooling water injection and discharging it in the direction of the mover 3. The steam treatment device 50 is fixedly installed on the upper part of the injection device 20, more specifically, on the upper part of the horizontal pipe 23, and sucks the vapor evaporated as the cooling water contacts the melt in a high temperature state, and returns it to the melt. In addition, it can be used as a cooling means for the melt.

The steam treatment device 50 covers the upper part of the mover 3 over a large area, and is disposed in front of the steam recovery shade 51 that collects and processes the steam that has risen and the spray nozzle 24 to ingot tray 2 before cooling water is sprayed. ) It will be exemplified as including a cooling fan 52 for downward blowing the steam recovered by the steam recovery shade 51 toward and a connection pipe 53 connecting the steam recovery shade 51 and the cooling fan 52. can

The steam recovered by the steam recovery shade 51 is forcibly sucked through the cooling fan 52 and then sprayed onto the ingot tray 2 moving in a row by the mover 3, so that the melted material directly contacts the cooling water It allows the air cooling action to be performed just before becoming.

That is, by not discharging the steam generated during the cooling process of the melt as it is, but by using it for cooling the melt, not only the cooling efficiency is increased, but also difficult-to-process steam can be treated more efficiently.

Meanwhile, in FIG. 2 , a dotted line represents a movement direction of cooling water, a two-dot chain line represents a movement direction of washing water, and a dotted line represents a movement direction of steam.

The embodiments of the present invention described above are merely exemplary, and those skilled in the art will appreciate that various modifications and equivalent other embodiments are possible therefrom. Therefore, it will be well understood that the present invention is not limited to the forms mentioned in the detailed description above. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims. It is also to be understood that the present invention includes all modifications, equivalents and alternatives within the spirit and scope of the present invention as defined by the appended claims.

1: melter
2: Ingot tray
3: mover
4: Cooler

Claims (5)

A melter for melting brass, a mover for moving a plurality of ingot trays containing melt discharged from the melter in a row, and a cooler installed on the path of the mover and cooling the melt contained in the ingot tray Ingot including In the automatic equipment,
the cooler,
a cooling water chamber disposed below the mover and storing cooling water;
a spraying device disposed above the mover and connected to the coolant chamber to spray the coolant stored in the coolant chamber to the top of the mover; and
A purifier disposed directly below the mover, connected to the coolant chamber, and recovering the coolant injected into the mover, purifying it, and returning it to the coolant chamber;
The purifier is
a recovery hopper unit fixedly installed directly below the mobile unit to recover the cooling water falling from the mobile unit;
a purification unit consisting of a pair of two sets, at least one of which is selectively connected to an upper portion of the cooling water chamber to receive cooling water, and a purification filter built-in to filter the cooling water;
a washing unit disposed at one side of the cooling water chamber and connected to a purifying unit not connected to the cooling water chamber among the pair of purifying units to clean the purifying unit; and
A moving unit that supports the pair of purifiers apart and rotates the purifiers to the position of the cooling water chamber or the washing unit so that each purifying unit is alternatively connected to the cooling water chamber and the washing unit,
Each of the pair of purification units,
a housing made of a cylindrical shape containing the purification filter, and having an upper and lower connectors extending from upper and lower ends, respectively; and
A diffusion member fixedly installed on the upper part of the purification filter inside the housing and diffusing and supplying the coolant flowing into the housing toward the purification filter;
The moving part,
An upper support plate formed in the form of a plate and having a pair of upper fixing holes through which upper connectors of each of the pair of housings are inserted to support the upper end of the housing;
a lower support plate spaced downward in parallel with the upper support plate, formed in the form of a plate, and having a pair of lower fixing holes through which the lower connectors of the pair of housings are inserted to support the lower end of the housing;
an interlocking shaft coupled through the center of the upper support plate and the lower support plate and interlocking the upper support plate and the lower support plate; and
A drive motor for rotationally driving the interlocking shaft; includes,
When the upper support plate and the lower support plate rotate in the synchronous direction according to the rotation of the interlocking shaft, the cooling water chamber and the purifying part respectively connected to the washing unit are rotated and moved to exchange positions with each other,
The injector is
a vertical pipe that is directly connected to the cooling water chamber and extends upward;
a first circulation pump installed in the vertical pipe to pump the cooling water stored in the cooling water chamber to the vertical pipe; and
A horizontal pipe branching from the vertical pipe and extending to the upper part of the mover, and having a plurality of spray nozzles coupled and installed along the longitudinal direction; includes,
The washing unit,
a washing water chamber in which washing water is stored and a washing water recovery port connected to a lower connector of the housing is formed at an upper end thereof;
a washing water pipe that is directly connected to the washing water chamber and extends directly above the upper support plate and has a washing water outlet connected to the upper connector of the housing at an end thereof;
a second circulation pump installed in the washing water pipe and pumping the washing water stored in the washing water chamber to the washing water pipe; and
A washing water filtration filter installed on the conduit of the washing water pipe and filtering the washing water moving through the washing water pipe;
Bearings are interposed between the upper connector and the upper fixing hole and between the lower connector and the lower fixing hole, so that the purification unit can rotate relatively on the upper support plate and the lower support plate,
A centrifugal separation unit installed adjacent to the purification unit connected to the washing unit and rotating the purification unit supported between the upper support plate and the lower support plate in place to centrifugally separate foreign substances collected in the purification filter;
A band-shaped silicon pad is formed on the circumferential surface of the housing,
The centrifugal separator,
a drum forming a contact with the silicon pad; and
Ingot automatic equipment comprising a; centrifugal motor for rotationally driving the drum so that the housing rotates in place. delete delete delete The method of claim 1,
the cooler,
The automatic ingot equipment device further comprising a vapor treatment device fixedly installed on the upper part of the injection device and sucking in the vapor generated by the cooling water injection and discharging it in the direction of the mover.

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