KR20110088997A - Sand cooling apparatus for regenerating equipment of molding sand - Google Patents

Abstract

PURPOSE: A sand cooling apparatus for a regenerating equipment of molding sand is provided to block through-holes of a lower case by blowing foreign materials included in sand by a high pressure air supplier. CONSTITUTION: A sand cooling apparatus for a regenerating equipment of molding sand comprises a lower case, a lower cover, a high pressure air supplier(300), a cooling water circulation pipe(400), and an upper cover. The lower case has an air inlet pipe connected to an air supply fan at one side thereof. The lower cover is configured with a bolt by passing a bolt insertion hole and an air discharge hole. The high pressure air supplier includes a main supply pipe(320) connected to the other side end of an air supply pipe(310) at the other end thereof. A cooling water circulation pipe(400) is installed in an air supply pipe at the upper space of the high pressure air supplier.

Description

Sand cooling apparatus for regenerating equipment of molding sand}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sand cooler for foundry sand regeneration equipment for cooling hot foundry sand separated from a mold.

In general, in the case of a molding sand used for making a mold, moldability, breathability, adaptability, etc. should be sufficiently considered, and it is also very important to grind the particles evenly because they vary greatly depending on the size of the particles.

In case of drying and using the collected naturally, there is no big problem because it is sorted and supplied during the collection process.

In the foundry sand regeneration facility, a cooling device for cooling the foundry sand in a high temperature state is required.

As a technology related to such a sand cooler for foundry sand regeneration facilities, "the method of recycling waste foundry sand" (Korean Patent Laid-Open Publication No. 1998-068759) discloses a technique for cooling a foundry sand using a cylindrical cooling rotary tube and a cooling fan.

In addition, a method and apparatus for low temperature regeneration of casting sand (Korean Patent Laid-Open Publication No. 1998-086777) discloses a technology in which a pipeline through which a casting sand passes is rotated and a refrigerant is passed through the pipeline.

However, such a technique has a problem that it is difficult to cool a large amount of molding sand generated in a large mold at a high speed.

That is, there was a problem in that enormous power is consumed to rotate the pipeline through which the foundry sand passes, and it is difficult to cool and process a large amount of foundry sand because circulation and discharge of the refrigerant passing through the pipeline are difficult.

KR, 10-1998-068759, (1998.10.26) KR, 10-1998-086777, (1998.12.05)

The four-cooler for foundry sand regeneration facility of the present invention is to solve the problems caused by the prior art, and in the state where a plurality of cooling water circulation pipes are disposed in the lower space of the upper cover, the sandblaster using a high-pressure air supply device is used. It is intended to allow cooling while moving.

More specifically, in a state in which a plurality of air supply pipes through which high pressure air is discharged are arranged side by side at the lower side of the cooling water circulation pipe, one side by high pressure air discharged from the air supply pipe by sequentially opening and closing a valve connected to each air supply pipe. It is going to move in the direction to be discharged.

In particular, the foreign material such as scrap contained in the casting sand is to be discharged smoothly while preventing the blown of the lower case to blow periodically by the high-pressure air supply device.

At this time, the lower case and the lower cover connected to the air supply fan are installed in the lower part of the high-pressure air supply device, and the molding sand is formed inside the lower case by forming a plurality of minute through holes having a thickness of 0.5 to 1.5 mm using a sack or the like on the lower cover side. It is to supply air smoothly without being introduced into the tank.

In addition, a plurality of casting partitions are sequentially installed between the cooling water circulation pipes, and the casting partitions are formed in the upper portion, and the spaces in which the casting sands are arranged are alternately arranged so that the adjacent casting holes are alternately disposed so that the casting sand is installed. By moving from to zigzag to increase the contact area with the cooling water circulation pipe to improve the cooling efficiency.

In addition, one side unit and the other unit are connected to both ends of the coolant pipes, and a plurality of layer partition plates are installed on one side unit and the other unit, and a space is formed between the end of the layer partition plate and the unit wall, but the space is zigzag. It is to form a, so that the cooling water is discharged while circulating as much as possible to improve the cooling efficiency.

In addition, by installing a fixed frame to the high-pressure air supply device, and to install the opening and closing door for opening and closing the air supply pipe insertion hole on the other side wall of the fixed frame to facilitate the cleaning of the inside of the pipe.

In order to solve the above problems, the four-cooler for foundry sand regeneration facility of the present invention is formed in a rectangular box shape, and a lower case having an air inlet pipe connected to an air supply fan on one side; A cover plate which is installed on the upper part of the lower case and has a plurality of rectangular air discharge holes, and is formed with a plurality of circular bolt insertion holes having a smaller size than the air discharge holes while corresponding to each air discharge hole; A lower cover comprising a washer having a thickness of 0.5 to 1.5 mm installed between the cover plate and the stool, and a bolt installed through the bolt insertion hole and the air discharge hole; A plurality of air supply pipes formed with a plurality of air discharge holes inclined downward at a predetermined interval are installed on the lower cover at a plurality of predetermined intervals, one end of each air supply pipe is blocked, and a solenoid valve is installed at the other end. A high pressure air supply device comprising a main supply pipe connected to the compressor at the other end of each air supply pipe; A plurality of coolant circulation pipes having one side connected to an external coolant supply device and installed in parallel with an air supply pipe in an upper space of the high pressure air supply device; The upper part covers the upper portion of the lower cover to cover the upper portion of the high pressure air supply device and the cooling water circulating pipe, the upper and the upper side is formed on the one side and the other side of the casting sand supply port and the casting sand discharge port, the air outlet is formed on the top; It is configured by.

At this time, a plurality of casting partitions are sequentially installed between the cooling water circulation pipes inside the upper cover, and each of the casting partitions has an incision formed on one side thereof, and adjacent casting partitions are staggered from each other. It is characterized by being arranged.

One side unit and the other unit formed in a rectangular box form at both ends of the cooling water circulation pipes, respectively, any one or two selected from one side unit and the other unit is connected to the external cooling water supply device on one side, the other side of the cooling water A discharge pipe is installed, and a plurality of layer partition plates for bending layers are installed in one unit and the other unit, and the layer partition plates of the other unit have a zigzag space formed between one end and the side wall surface. It is done.

In addition, the air discharge hole formed in each air supply pipe of the high pressure air supply device is characterized in that it is formed inclined downward toward the casting sand discharge port direction of the upper cover.

In addition, the high-pressure air supply device is installed on the lower cover, and is formed in an open shape up and down, and is further provided with a fixed frame in which a plurality of air supply pipe insertion holes are formed on one side and the other side wall, the other side The wall is characterized in that the opening and closing door for opening and closing the air supply pipe insertion hole is installed.

According to the present invention, while a plurality of cooling water circulation pipes are arranged in the lower space of the upper cover, cooling is performed while moving the molding sand using a high pressure air supply device.

More specifically, in a state in which a plurality of air supply pipes through which high pressure air is discharged are arranged side by side at the lower side of the cooling water circulation pipe, one side by high pressure air discharged from the air supply pipe by sequentially opening and closing a valve connected to each air supply pipe. Move in the direction and is easily discharged.

In particular, foreign substances such as scrap contained in the foundry sand can be smoothly discharged while preventing the blown of the lower case by periodically blowing in the wind by the high-pressure air supply device.

At this time, the lower case and the lower cover connected to the air supply fan is installed in the lower part of the high-pressure air supply device, but by forming a plurality of minute through holes of 0.5 ~ 1.5 mm thickness in the lower cover side without casting sand flowing into the inner space of the lower case It will supply air smoothly.

In addition, a plurality of casting partitions are sequentially installed between the cooling water circulation pipes, and the casting partitions are formed in the upper portion, and the spaces in which the casting sands are arranged are alternately arranged so that the adjacent casting holes are alternately disposed so that the casting sand is installed. By moving from to zigzag to increase the contact area with the cooling water circulation pipe to improve the cooling efficiency.

In addition, one side unit and the other unit are connected to both ends of the coolant pipes, and a plurality of layer partition plates are installed on one side unit and the other unit, and a space is formed between the end of the layer partition plate and the unit wall, but the space is zigzag. The cooling efficiency is improved by allowing the cooling water to be discharged while circulating the inner space as much as possible.

In addition, it is easy to clean the inside of the pipe by installing a fixed frame to the high-pressure air supply device, and the opening and closing door for opening and closing the air supply pipe insertion hole on the other side wall of the fixed frame.

1 is an exploded perspective view showing a four-cooler for foundry sand regeneration facility of the present invention.
Figure 2 is a perspective view showing a four-cooler for foundry sand regeneration facility of the present invention.
Figure 3 is a schematic cross-sectional view showing a four-cooler for foundry sand regeneration facility of the present invention.
Figure 4 is an exploded perspective view showing an example of the layer separation plate formed in one side unit and the other side unit in the present invention.
Figure 5 is a schematic cross-sectional view showing the flow of air in the upper cover plate in the present invention.

The four-cooler for sand casting regeneration equipment of the present invention is largely composed of a lower case 100, a lower cover 200, a high pressure air supply device 300, a cooling water circulation pipe 400, the upper cover.

Hereinafter, each component of the four-cooler for foundry sand regeneration plant of the present invention will be described in more detail with reference to the accompanying drawings.

The lower case 100, which is a component of the present invention, is formed in a rectangular box shape as shown in the drawing, and an air inlet pipe 110 connected to an air supply fan is installed at one side.

The illustration of the air supply fan is omitted in the drawing.

The lower cover 200, which is a component of the present invention, includes a cover plate 210, a chord 220, a washer 230, and a bolt 240.

The cover plate 210 is installed on the upper portion of the lower case 100, and a plurality of rectangular air discharge holes 211 are formed.

The cover plate 210 and the lower case 100 are flanged along the circumference of the lower case 100, as shown, is configured to be bolted to the cover plate 210.

The air discharge hole 211 of the cover plate 210 may be formed in various ways, such as width 5 ~ 6 mm, length 30 ~ 300 mm.

The chord 220 is installed on the top of the cover plate 210 as shown, a plurality of circular bolt insertion hole 221 having a diameter corresponding to the width of the air discharge hole 211 of the cover plate 210 Is formed.

At this time, the installation direction of the chock 220 is preferably installed so as to be perpendicular to the longitudinal direction that the casting sand proceeds, that is, the cooling water circulation pipe 400 to be described later so as not to interfere with the movement of the molding sand.

The washer 230 is installed between the cover plate 210 and the cap 220, and is configured to have a thickness of 0.5 to 1.5 mm and an inner diameter of about 5 to 6 mm.

The bolt 240 is installed through the chock 220, the washer 230, the cover plate 210 from the top to the bottom.

That is, it is installed through the bolt insertion hole 221 and the air discharge hole 211, the nut 240 may be selectively fastened to such a bolt (240).

In this configuration, the washer 230 is installed in the upper portion of the air discharge hole 211 formed in the cover plate 210 so that the air is moved from the bottom upwards as much as the thickness of the washer 230, but the cover plate ( The casting sand seated on the upper portion is configured to prevent the inflow into the air discharge hole 211 by the cap 220.

In addition, the thickness of the washer 230 is a configuration that prevents the sand from flowing into the gap between the cover plate 210 and the cap 220 to the maximum.

The high-pressure air supply device 300, which is a component of the present invention, has a plurality of air supply pipes 310 in which a plurality of air discharge holes 311 are formed to be inclined downward at regular intervals on the upper portion of the lower cover 200 at regular intervals. Installed and configured.

At this time, one end of the air supply pipe 310 is blocked, the other end is provided with a solenoid valve 312, the other end of each air supply pipe 310 is connected to one main supply pipe 320, the main The supply pipe 320 is connected to the compressor.

That is, the high pressure air introduced into the main supply pipe 320 through the compressor is introduced into the air supply pipe 310 according to the opening and closing of each solenoid valve 312, and then discharged through the air discharge hole 311.

At this time, opening and closing of the solenoid valve 312 is the most preferred embodiment to open and close each air supply pipe 310 sequentially in the direction in which the molding sand is supplied and discharged.

The high-pressure air supply device 300 is formed in the form of open up and down as shown in order to fix each air supply pipe 310 at a predetermined position on the lower cover 200, one side and the other side wall surface It is preferable that the air supply pipe insertion hole 331 is formed in the.

In addition, the fixing frame 330 is bolted to the cover plate 210 of the lower by forming a flange around the upper and lower circumference, it is preferable to bolt to the upper cover 500 to be described later.

In the installation of the fixed frame 330 as described above, the opening and closing door 340 for opening and closing the air supply pipe insertion hole 331 on the other side wall of the fixed frame 330 as shown in the interior of the air supply pipe 310 It would be desirable to be able to clean.

This is to make it easy to clean the particles when the fine sand or dust is introduced into the air supply pipe (310).

In constructing the high-pressure air supply device 300, the air discharge hole 311 formed in each air supply pipe 310 is formed to be inclined downward toward the casting sand discharge port 520 of the upper cover 500, the casting sand. It is desirable to be able to move smoothly.

Cooling water circulation pipe 400 is a component of the present invention, one side is connected to the external cooling water supply device as shown, a plurality of the high pressure air supply device 300 is installed in parallel with the air supply pipe 310 It is configured.

At this time, the cooling water circulation pipe 400 is preferably using a steel pipe in place of the copper fin tube so that foreign matter is not caught between the fins.

Specifically, when the copper tube of the fin tube is used, the thermal conductivity is improved, but foreign matter is constricted between the fin tubes, which is an advantageous condition that the thermal conductivity is lowered and the wire is caught, but in the present invention, it is reduced by using a steel pipe. The wearability is also excellent compared to the copper tube.

A separate illustration of the cooling water supply device will be omitted.

The cooling water circulation pipe 400 may be discharged by receiving the cooling water separately from the external cooling water supply device for each circulation pipe, it is uneconomical.

To this end, one side unit 410 and the other side unit 420 formed in a rectangular box shape are connected to both ends of the respective cooling water circulation pipes 400, and one side unit 410 has an external cooling water supply device. The pipe is connected, and the other side unit 420 is preferably provided with a cooling water discharge pipe 440 so that the cooling water is discharged.

At this time, as shown in order to have a constant flow path of the zigzag cooling system, one side unit 410 and the other side unit 420 is provided with a plurality of layer partition plates 430 for bending the layer, and the other unit ( The layer separation plate 430 of 420 may be formed in a zigzag space between one end and the side wall surface.

That is, the lower layer partition plate 430 forms a space so as not to contact the left side wall surface of the other side unit 420, and the upper layer partition plate 430 does not touch the right side wall surface of the other side unit 420. The cooling water is circulated while reciprocating the one side unit 410 and the other unit 420 in a zigzag manner as much as possible.

This configuration makes it possible to circulate the coolant in a zigzag manner much more simply than installing the pipes in a zigzag fashion.

At this time, the cooling water discharge pipe 440 is not limited to being installed only in the other side unit 420, it may be optionally installed in one side unit 410.

In the figure, the supply and discharge of the cooling water is made on the other side unit 420, and the cooling water partition 431 for dividing the internal space of the other side unit 420 in half is configured to make the circulation of the cooling water as long as possible.

In the figure, an example in which one side unit 410 and the other side unit 420 are configured in parallel with each other is configured to further improve cooling efficiency.

On the other hand, the movement of the molding sand can also be moved in a zig-zag manner as much as possible to further improve the cooling efficiency.

To this end, as shown in the figure, a plurality of casting partitions 450 are sequentially installed between the cooling water circulation pipe 400 inside the upper cover 500, and each of the casting partitions 450 is located on one side of the upper portion. An incision 451 is formed, and adjacent casting use partitions 450 may be arranged such that the incisions 451 are staggered from each other.

In this case, the cutout 451 is shown as being cut only to one side of the upper portion, but is not limited thereto, and may be configured to cut to the bottom end.

The upper cover 500, which is a component of the present invention, covers the upper portion of the high pressure air supply device 300 and the cooling water circulation pipe 400, while the bottom portion covers the edge of the lower cover 200, as shown. The casting sand supply port 510 and the casting sand discharge port 520 are formed at the other side, respectively, and the air discharge port 530 is formed at the upper side.

At this time, the internal confirmation window may be installed as shown in the figure so that the state of the interior.

In addition, the air outlet 530 may be provided with a filter to prevent the casting sand is discharged to the outside through the air outlet 530.

Or, the air outlet 530 will be more preferably configured to collect the dust collector connected to the pipe.

In this case, when the air outlet 530 is connected to the dust collector and the pipe, coarse particles sucked into the dust collector in the dust collecting process may damage the bag filter and cause clogging in the duct.

In order to solve this problem, it is more preferable to apply a separation device applying Bernoulli's theorem as shown.

Specifically, the inlet pipe (544) is connected to the air outlet 630, the inlet pipe (544) is installed at the end of the case type separation device 540 having a larger volume than the inlet pipe (544), the separator 540 Discharge pipe 543 is installed on one side of the) connected to the dust collector, the pipe of the discharge pipe 543 is formed smaller than the volume of the separator 540.

In addition, the locking plate 541 may be installed on the upper side of the separator 540, and the outlet 542 may be installed below the separator 540.

In this configuration, since the inside volume of the separator 540 is larger than the inlet pipe 544 or the outlet pipe 543, the air introduced into the separator 540 has a low flow rate, and the molding sand or the foreign matter contained in the air is caught by a locking plate ( After hitting 541, the discharge is discharged through the discharge port 542, and only air moves to the dust collector through the discharge pipe 543, so that the defect of the dust collector is generated less.

Referring to the main operation of each device of the present invention configured as described above are as follows.

First, the casting sand is introduced into the inner space through the casting sand supply port 510 of the upper cover 500 is configured to be discharged through the casting sand outlet 520.

In this process, a plurality of cooling water circulation pipes 400 are installed in the inner space of the upper cover 500 so that the foundry sand is cooled by the cooling water passing through the cooling water circulation pipe 400.

The movement of the casting sand is moved from one side to the other side by the high pressure air supply device 300 installed in the lower space of the cooling water circulation pipe 400.

On the other hand, the basic air flow is discharged through the air outlet 530 of the upper cover 500, after the outside air flows through the lower case 100 installed in the lower portion of the high-pressure air supply device 300.

That is, when the air temperature inside the upper cover 500 is increased by the inlet of the foundry sand, it is discharged through the air outlet 530, so the temperature inside is continuously lowered by the external air and the cooling water circulation pipe 400 continuously introduced. Will be in a state.

In addition, the high pressure air introduced into the interior by the high pressure air supply device 300 is eventually discharged to the outside through the air outlet 530.

In this process, foreign substances such as scraps included in the foundry sand can be minimized from being introduced into the lower case 100 into the inner space by the high-pressure air supply device 300, and the lower portion installed on the lower case 100. Casting sand, scrap, etc. are prevented from flowing into the inner space of the lower cover 200 by the chord 220 and the washer 230 constituting the cover 200.

100: lower case 110: air inlet pipe
200: lower cover 210: cover plate
211: air discharge hole 220: bed
221: bolt insertion hole 230: washer
240: bolt 300: high pressure air supply device
310: air supply pipe 311: air discharge hole
312: solenoid valve 320: main supply pipe
330: fixed frame 331: air supply pipe insertion hole
340: opening and closing door 400: cooling water circulation pipe
410: one side unit 420: the other side unit
430: layer separation plate 431: cooling water partition
440: cooling water discharge pipe 450: casting use partition
451: incision 500: upper cover
510: foundry sand supply port 520: foundry sand outlet
530: air outlet 540: separator
541: stopping plate 542: outlet
543: discharge pipe 544: inlet pipe

Claims (5)

In the four-cooler for foundry sand regeneration equipment,
A lower case 100 formed in a rectangular box shape and having an air inlet pipe connected to an air supply fan at one side thereof;
The cover plate 210 is installed on the upper portion of the lower case 100, the plurality of rectangular air discharge holes 211 is formed, and the circular bolt insertion hole 221 corresponding to each air discharge hole 211. ) Is formed with a plurality of poles 220 are installed on the cover plate 210, the cover plate 210 and the washer 230 is installed between the cover plate 210 and the pole 220, and the bolt insertion A lower cover 200 formed of a bolt 240 installed through the hole 221 and the air discharge hole 211;
A plurality of air supply pipes 310 having a plurality of air discharge holes 311 formed to be inclined downward at a predetermined interval are installed on the lower cover 200 at a predetermined interval, and one end of each air supply pipe 310 is A high pressure air supply device 300 which is clogged and has a solenoid valve 312 installed at the other end, and a main supply pipe 320 connected to the compressor at the other end of each air supply pipe 310;
A plurality of coolant circulation pipes 400 having one side connected to an external coolant supply device and installed in parallel with an air supply pipe 310 in an upper space of the high pressure air supply device;
A bottom portion covers the upper portion of the lower cover 200 and covers the upper portion of the high-pressure air supply device 300 and the cooling water circulation pipe 400, and a casting sand supply port 510 and a casting sand outlet 520 are formed at one side and the other side, respectively. Consists of, including; an upper cover 500, the air outlet 530 is formed on the top;
Four-cooler for foundry sand regeneration plant.
The method of claim 1,
A plurality of casting partitions 450 are sequentially installed between the cooling water circulation pipe 400 in the upper cover 500, and each of the casting partitions 450 has an air supply pipe 451 formed at an upper side thereof. And, the adjacent casting use partition 450 is characterized in that the air supply pipe 451 is arranged in a staggered staggered with each other,
Four-cooler for foundry sand regeneration plant.
The method of claim 1,
It is connected to one side unit 410 and the other side unit 420 formed in a rectangular box shape at both ends of the cooling water circulation pipe 400, either one or two selected from one side unit 410 and the other side unit 420 An external cooling water supply device is connected to one side, and a cooling water discharge pipe is installed at the other side, and a plurality of layer separation plates 430 are formed at one side of the unit 410 and the other unit 420 to bend a layer. However, the layer separation plate 430 of the other side unit 420 is characterized in that the space is formed in a zigzag between one end and the side wall surface,
Four-cooler for foundry sand regeneration plant.
The method of claim 1,
Air discharge holes 311 formed in each of the air supply pipe 310 of the high-pressure air supply device 300 is characterized in that the inclined downward toward the molding sand discharge port 520 of the upper cover 500,
Four-cooler for foundry sand regeneration plant.
The method of claim 1,
The high-pressure air supply device 300 is installed on the lower cover 200, is formed in an open shape up and down, a fixed frame in which a plurality of air supply pipe insertion holes 331 is formed on one side and the other side wall 330 is further provided, characterized in that the other side wall is provided with an opening and closing door 340 for opening and closing the air supply pipe insertion hole 331,
Four-cooler for foundry sand regeneration plant.

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