KR20200084671A - Jig module for carbon block producing apparatus - Google Patents

Abstract

The present invention relates to a jig module for a carbon block manufacturing apparatus to efficiently manage and operate the carbon block manufacturing apparatus. According to the present invention, the jig module for a carbon block manufacturing apparatus is moved by a transfer mechanism, and comprises: a base; an external mold installed on one surface of the base and defining an external shape of a carbon block; an external heater for heating the external mold; an external temperature sensor measuring the temperature of the external mold; a lower plate functioning as a bottom for an internal space of the external mold; and a temperature control panel controlling the external heater to maintain the temperature of the external mold at a preset range.

Description

Jig module for carbon block manufacturing equipment {JIG MODULE FOR CARBON BLOCK PRODUCING APPARATUS}

The present invention relates to a jig module for a carbon block manufacturing apparatus, and more particularly, to a jig module for a carbon block manufacturing apparatus that can be moved by a transport mechanism.

Carbon blocks are widely used as filters that are installed in water purifiers and remove chlorine, organic matter, and various odors in water.

These carbon blocks are often manufactured by injecting activated carbon and a binder for producing carbon blocks into a molding machine and extruding them at a specific temperature and pressure.

However, according to this, the pores of the activated carbon are occluded by the binder due to the pressure in the extrusion process, thereby deteriorating the performance (for example, VOC removal performance of activated carbon).

The present invention provides a jig module for a carbon block manufacturing apparatus that enables efficient management/operation of the carbon block manufacturing apparatus.

The jig module for a carbon block manufacturing apparatus according to the present invention is a jig module for a carbon block manufacturing apparatus that can be moved by a transport mechanism, installed on a base, one surface of the base, and an external mold defining an external shape of the carbon block, the An external heater for heating an external mold, an external temperature sensor for measuring the temperature of the external mold, a lower plate serving as a floor to the internal space of the external mold, and the temperature of the external mold to maintain a preset range. It may include a temperature control panel for controlling the external heater.

In addition, the external heaters may be installed in plural and arranged at predetermined intervals along the height direction of the external mold.

In addition, the lower plate is installed to be movable up and down with respect to the outer mold, the base may be formed with a hole for passing through the compression mechanism for pressing the lower plate upward from the lower side than the base.

In addition, it is installed on one surface of the base, and includes an inner core disposed inside the outer mold to define an inner shape of the carbon block, wherein the lower plate has an outer diameter corresponding to the inner diameter of the outer mold and an inner diameter of the inner core. It is formed in an annular shape corresponding to the outer diameter of, it can be installed to be movable up and down with respect to the outer mold and the inner core.

Also includes an internal heater for heating the inner core and an inner temperature sensor for measuring the temperature of the inner core, and the temperature control panel can control the inner heater so that the temperature of the inner core maintains a preset range. .

In addition, the inner heater may be embedded in the body of the inner core.

In addition, a plurality of the internal heaters may be arranged at predetermined intervals along the height direction of the internal core.

In addition, it is made of a conductive material and is installed on the other surface of the base, and may include a terminal for receiving power.

The jig module for a carbon block manufacturing apparatus according to the present invention is made by a plurality of components (for example, a base, an outer mold, an inner core, an outer heater, an inner heater, a temperature control panel, etc.) to be moved by a transport mechanism as a set, This makes it possible to more efficiently manage/operate the carbon block manufacturing apparatus.

1 is a front view of the jig module.
2 is a plan view of the jig module.
3 is a side view of the jig module.
4 is a block diagram of a carbon block manufacturing apparatus.
5 is a side view of the carbon block manufacturing apparatus when the jig module reaches the raw material supply mechanism.
Fig. 6 is a side view of the carbon block manufacturing apparatus when the jig module reaches the preliminary raw material compression mechanism.
7 is a side view of the carbon block manufacturing apparatus when the jig module reaches the raw material compression mechanism.
8 is a side view of the carbon block manufacturing apparatus when the jig module reaches the carbon block compression mechanism.
9 is a side view of the carbon block manufacturing apparatus when the jig module reaches the carbon block discharge mechanism.
10 is a flowchart of a carbon block manufacturing method.

A jig module 100, a carbon block manufacturing apparatus including the jig module 100, and a carbon block manufacturing method will be described in detail with reference to the drawings.

1 is a front view of the jig module 100, FIG. 2 is a plan view of the jig module 100, and FIG. 3 is a side view of the jig module 100.

1 to 3, the jig module 100 includes a base 110, an outer mold 120, an inner core 130, an outer heater 140, an inner heater 150, an external temperature sensor (not shown), It includes an internal temperature sensor (not shown), a lower ring 160, a temperature control panel 170, and a terminal 180.

The base 110 is generally formed in a plate shape. Accordingly, an outer mold 120, an inner core 130, and a temperature control panel 170 are installed on the upper surface of the base 110, and a terminal 180 is installed on the lower surface of the base 110.

In the drawing, the base 110 is illustrated as being generally formed in a square shape, but may be formed in a different shape, such as an oval, if necessary.

In addition, the base 110 has a lower rod 570 of the raw material compression mechanism 500 to be described later, a lower rod 670 of the carbon block compression mechanism 600 and a rod 720 of the carbon block discharge mechanism 700 penetrates. And a hole for passing is formed.

The outer mold 120 is formed in a tubular shape to accommodate the powdery raw material for manufacturing the carbon block to define the outer shape of the carbon block, and the inner core 130 is formed in a rod shape, and disposed inside the outer mold 120 Define the internal shape of the carbon block.

In the drawing, the outer mold 120 is formed in a circular shape, and the inner core 130 is also formed in a circular shape, which is illustrated as being oriented parallel to the central axis of the outer mold 120. In this case, the carbon block will be made into a hollow cylindrical shape with an empty space along its central axis. However, the outer mold 120 and the inner core 130 may be formed in different shapes, such as a square or a hexagon, if necessary.

The outer mold 120 and the inner core 130 are fixedly installed on the upper surface of the base 110. In addition, the outer mold 120 and the inner core 130 may be installed in plural.

In the drawing, the outer mold 120 and the inner core 130 are illustrated as being installed in four, but may be installed in one, two, three, or five or more as needed.

The external heater 140 is installed in the external mold 120 to heat the external mold 120. For example, the external heater 140 may be attached to the inner circumferential surface of the outer mold 120, may be attached to the outer circumferential surface of the outer mold 120 as shown in the drawing, or may be embedded in the wall of the outer mold 120. have.

The external heater 140 may be formed over the entire circumference of the external mold 120. For example, the external heater 140 may be integrally extended along the circumferential direction of the external mold 120, or may be divided into a plurality and arranged at predetermined intervals along the circumferential direction of the external mold 120.

In addition, the external heater 140 may be formed over the entire height of the external mold 120. For example, the external heater 140 may be integrally extended along the height direction of the external mold 120 or may be divided into a plurality and arranged at predetermined intervals along the height direction of the external mold 120.

The inner heater 150 is installed on the inner core 130 to heat the inner core 130. For example, the inner heater 150 may be attached to the outer circumferential surface of the inner core 130, or may be embedded in the body of the inner core 130 as shown in the figure.

The inner heater 150 may be formed over the entire height of the inner core 130. For example, the inner heater 150 may extend integrally along the height direction of the inner core 130, or may be divided into a plurality and arranged at predetermined intervals along the height direction of the inner core 130.

According to this, the outer heater 140 heats the outer mold 120 to heat the inner space of the outer mold 120 from the outside, and the inner heater 150 heats the inner core 130 to thereby heat the outer mold 120. ) Can heat the inner space from the inside. Therefore, the entire interior space of the outer mold 120 can be uniformly and quickly heated.

The external temperature sensor measures the temperature of the outer mold 120, and the internal temperature sensor measures the temperature of the inner core 130.

If the external temperature sensor and the internal temperature sensor can measure the temperature of the outer mold 120 and the inner core 130, their specific configuration itself is not particularly limited, and thus detailed description thereof will be omitted.

The lower ring 160 is a floor for the inner space of the outer mold 120, and is installed to be movable up and down with respect to the outer mold 120 and the inner core 130.

To this end, the lower ring 160 is formed in an annular shape in which the outer diameter is substantially equal to or slightly smaller than the inner diameter of the outer mold 120, and the inner diameter is substantially equal to or slightly larger than the outer diameter of the inner core 130.

Here, the term "slightly smaller or larger" means that the inner circumferential surface of the outer mold 120 and the outer circumferential surface of the lower ring 160 are in close contact, and the outer circumferential surface of the inner core 130 and the inner circumferential surface of the lower ring 160 are in close contact. When the raw material is supplied to the outer mold 120, the raw material can be prevented from leaking into the gap therebetween, but the lower ring 160 moves smoothly up and down with respect to the outer mold 120 and the inner core 130. It means the degree that can be allowed.

The temperature control panel 170 controls the external heater 140 and the internal heater 150 so that the temperature of the external mold 120 and the inner core 130 is maintained in a preset range.

For example, if the temperature of the external mold 120 is set to be maintained at 120°C to 180°C, the temperature control panel 170 operates the external heater 140 when the measured value of the external temperature sensor is lower than 120°C, When the value of the external temperature sensor is higher than 180°C, the operation of the external heater 140 may be stopped. Similarly, if the temperature of the inner core 130 is set to be maintained at 100°C to 140°C, the temperature control panel 170 operates the inner heater 150 when the measured value of the inner temperature sensor is lower than 100°C, and the inner temperature When the measured value of the sensor is higher than 140°C, the operation of the internal heater 150 may be stopped. Of course, the above values are only examples, and may be set to any other range depending on the composition of the raw materials.

The temperature control panel 170 may independently control the external heater 140 and the internal heater 150. In addition, as described above, if the external heater 140 and the internal heater 150 are divided into a plurality, the individual external heater 140 and the internal heater 150 can be independently controlled. Accordingly, the inner space of the outer mold 120 may be more uniformly heated as a whole.

To this end, the temperature control panel 170 for each of the external heater 140 and the internal heater 150, the external mold temperature display unit 171, the external mold temperature setting unit 172, the internal core temperature display unit 173, the interior And a core temperature setting unit 174.

The terminal 180 is made of a conductive material, and is installed at a predetermined position on the lower surface of the base 110.

Hereinafter, the carbon block manufacturing apparatus will be described.

4 is a configuration diagram of a carbon block manufacturing apparatus, which corresponds to a plan view. 5 is a side view of the carbon block manufacturing apparatus when the jig module 100 reaches the raw material supply mechanism 300, and FIG. 6 is a carbon block when the jig module 100 reaches the preliminary raw material compression mechanism 400. A side view of the manufacturing apparatus, FIG. 7 is a side view of the carbon block manufacturing apparatus when the jig module 100 reaches the raw material compression mechanism 500, and FIG. 8 is a jig module 100 having the carbon block compression mechanism 600 It is a side view of the carbon block manufacturing apparatus when it reaches, and FIG. 9 is a side view of the carbon block manufacturing apparatus when the jig module 100 reaches the carbon block discharge mechanism 700.

4, the carbon block manufacturing apparatus includes a jig module 100, a transport mechanism 200, a raw material supply mechanism 300, a preliminary raw material compression mechanism 400, a main raw material compression mechanism 500, and a carbon block compression mechanism ( 600) and a carbon block discharge mechanism 700.

Since the jig module 100 is as described above with reference to FIGS. 1 to 3, redundant description thereof will be omitted.

The transport mechanism 200 serves to transport the jig module 100 along the edge of any closed figure.

In the drawing, the transport mechanism 200 is illustrated as transporting the jig module 100 along the edge of the rectangle. In addition, in the drawing, it is illustrated that the transfer mechanism 200 transfers the jig module 100 using a caterpillar. Of course, if the transfer mechanism 200 can perform the corresponding role, it may be made of other configurations, but for convenience of understanding, a description will be given of the case where the transfer mechanism 200 is made as shown in the drawings.

In this case, the transport mechanism 200 includes a first caterpillar 210, a second caterpillar 220, a third caterpillar 230, a fourth caterpillar 240, and a first rail 250 , A second rail 260, a third rail 270, a fourth rail 280 and a brush 290.

4, the first caterpillar 210 extends along the upper side of the rectangle, and the second caterpillar 220 extends along the lower side of the rectangle.

In addition, the third caterpillar 230 is movably installed between the left end of the first caterpillar 210 and the left end of the second caterpillar 220 along the left side of the rectangle, and the fourth caterpillar The part 240 is movably installed between the right end of the first caterpillar 210 and the right end of the second caterpillar 220 along the right side of the rectangle.

Accordingly, the jig module 100 moves from the upper left to the upper right by the first caterpillar 210, moves from the upper right to the lower right along with the fourth caterpillar 240, and the second caterpillar By moving from the lower right to the lower left by 220, the third caterpillar 230 can be circulated clockwise by moving from the lower left to the upper left.

The first rail 250 extends along the first caterpillar 210, and the second rail 260 extends along the second caterpillar 220.

In addition, the third rail 270 extends along the movement path of the third caterpillar 230, and the fourth rail 280 extends along the movement path of the fourth caterpillar 240, the third infinity The track portion 230 and the fourth caterpillar portion 240 are prevented from being separated.

The brush 290 is connected to an external power source. In addition, the brush 290 is made of a conductive material, the terminal 180 of the jig module 100 while the jig module 100 is moved by the caterpillar 210, 220, 230, 240, the brush 290 It is installed at a predetermined position on the upper surface of the rail (250, 260, 270, 280) to be in contact with.

In particular, a plurality of brushes 290 may be installed, and may be arranged at predetermined intervals along the rails 250, 260, 270, 280. In addition, at this time, the terminal 180 may extend between two brushes 290 adjacent to each other. According to this, while the jig module 100 moves along the rails 250, 260, 270, and 280, the terminal 180 can be maintained in contact with at least one brush 290 at all times. Therefore, the jig module 100 may be continuously supplied with power through the brush 290 from an external power source.

If the jig module 100 is directly connected to an external power source by an electric wire, the electric wire may be twisted or caught in other components while the jig module 100 is moved, and thus the transmission path of the jig module 100 may be damaged. There is a problem that the degree of freedom in design can be limited.

However, if the jig module 100 is supplied with power through the terminal 180 and the brush 290 as described above, there is an advantage of not requiring a wire.

5, the raw material supply mechanism 300 serves to supply raw materials to the outer mold 120 of the jig module 100.

The injection hole 310 of the raw material supply mechanism 300 is disposed above the jig module 100 and can be moved downward by, for example, a hydraulic cylinder or an actuator.

At this time, the injection hole 310 is formed in a tubular outer diameter is smaller than the inner diameter of the outer mold 120, the inner diameter is larger than the outer diameter of the inner core 130.

Accordingly, the injection hole 310 starts to be injected into the outer mold 120 at a predetermined depth, and the raw material is injected, and as the raw material is injected, it may gradually move upward.

If the outer mold 120 and the inner core 130 are already heated by the outer heater 140 and the inner heater 150, if the inlet 310 drops the raw material from the upper side than the outer mold 120, the raw material There is a problem that it is scattered in all directions by convection or sticks to the inner circumferential surface of the outer mold 120 and the outer circumferential surface of the inner core 130, and cannot be properly stacked from the bottom of the outer mold 120.

However, if the injection port 310 is inserted into the external mold 120 to a predetermined depth and then gradually moves upward as the raw material is injected, there is an advantage that the raw material can be efficiently stacked from the bottom of the external mold 120. .

6, the preliminary raw material compression mechanism 400 is disposed downstream (section C in the case of FIG. 4) than the raw material supply mechanism 300, and serves to primarily compress the raw material of the external mold 120.

To this end, the preliminary raw material compression mechanism 400 includes a piston 410, a rod 420, a pressure ring 430, and a guide 440.

The piston 410 is disposed above the jig module 100 and can be moved downward by, for example, a hydraulic cylinder or an actuator.

The rod 420 is coupled to the bottom (piston head) 411 of the piston 410, and the pressure ring 430 is coupled to the bottom of the rod 420, and moves together with the piston 410.

At this time, the pressure ring 430 has an outer diameter substantially the same as or slightly smaller than the inner diameter of the outer mold 120, and the inner diameter is substantially the same or slightly larger than the outer diameter of the inner core 130. Therefore, the raw material of the outer mold 120 can be compressed downward by further moving downward while the pressure ring 430 moves downward and is inserted into the outer mold 120.

The piston 410 and the rod 420 may be integrally formed together, or separately formed and coupled to each other.

The guide 440 is disposed below the piston head 411, and a hole is formed through which the rod 420 passes. Thus, the guide 440 may serve to guide the movement path of the rod 420 so that the pressure ring 430 can be accurately inserted into the outer mold 120.

However, the outer diameter of the piston head 411 is formed larger than the diameter of the hole of the guide 440. Therefore, the piston 410 can only move downward until the piston head 411 contacts the upper surface of the guide 440. Accordingly, the guide 440 may also serve to limit the piston 410 from being excessively moved downward.

Furthermore, the guide 440 is installed to be movable up and down, but is fixed to a specific height to adjust the moving distance of the piston 410, that is, the compression length of the raw material.

Referring to FIG. 7 further, the raw material compression mechanism 500 is disposed downstream (section D in the case of FIG. 4) than the preliminary raw material compression mechanism 400, and serves to compress the raw material of the outer mold 120 secondaryly. .

To this end, the preliminary raw material compression mechanism 500 includes an upper piston 510, an upper rod 520, a pressure ring 530, an upper guide 540, an upper length adjusting member 550, a lower piston 560, and a lower rod. 570, a lower guide 580 and a lower length adjustment member 590.

The upper piston 510 is disposed above the jig module 100 and can be moved downward by, for example, a hydraulic cylinder or an actuator.

The upper rod 520 is coupled to the lower end (piston head) 511 of the upper piston 510, and the pressure ring 530 is coupled to the lower end of the upper rod 520, and moves together with the upper piston 510. .

At this time, the pressure ring 530, like the pressure ring 430 of the preliminary raw material compression mechanism 400, the outer diameter is substantially the same as or slightly smaller than the inner diameter of the outer mold 120, and the inner diameter of the inner core 130 It is formed in an annular shape that is substantially the same as the outer diameter or slightly larger. Accordingly, the raw material of the outer mold 120 may be compressed downward by further moving downward while the pressure ring 530 moves downward and is inserted into the outer mold 120.

The upper piston 510, the upper rod 520 and the pressure ring 530 may be integrally formed together, or may be separately formed and coupled to each other.

The upper guide 540 is disposed below the piston head 511, and a hole is formed through which the upper rod 520 passes. Accordingly, the upper guide 540 may serve to guide the movement path of the upper rod 520 so that the pressure ring 530 can be accurately inserted into the outer mold 120.

However, the outer diameter of the piston head 511 is formed larger than the diameter of the hole of the upper guide 540. Therefore, the upper piston 510 can move downward only until the piston head 511 contacts the upper surface of the upper guide 540. Accordingly, the upper guide 540 may also serve to limit the upper piston 510 from being excessively moved downward.

The upper length adjusting member 550 is formed at a specific height, and is detachably coupled around the hole on the upper surface of the upper guide 540.

In the drawing, the upper length adjusting member 550 is illustrated as being formed in a bolt shape and fastened to the upper surface of the upper guide 540, but may be formed in other shapes, such as a plate shape, a tubular shape, and a rod shape, if necessary.

If such an upper length adjusting member 550 is installed, the upper piston 510 can now move downward only until the piston head 511 abuts the top of the upper length adjusting member 550. The lower the upper length adjusting member 550, the more the upper piston 510 can move downwards. On the other hand, the higher the upper length adjusting member 550, the smaller the upper piston 510 can move downward. will be.

Accordingly, a plurality of upper length adjusting members 550 of different heights are provided, and the compression length of the raw material can be easily adjusted by replacing and using an appropriate upper length adjusting member 550 as necessary.

The lower piston 560 is disposed below the jig module 100, and can be moved upward by, for example, a hydraulic cylinder or an actuator.

The lower rod 570 is coupled to the lower end (piston head) 561 of the lower piston 560 and moves together with the lower piston 560.

Accordingly, the lower rod 570 moves upward and further moves upward while in contact with the lower surface of the lower ring 160, thereby compressing the raw material of the outer mold 120 upward through the lower ring 160.

The lower piston 560 and the lower rod 570 may also be integrally formed together, or separately formed and coupled to each other.

The lower guide 580 is disposed above the piston head 561, and a hole is formed through which the lower rod 570 passes. Accordingly, the lower guide 580 may serve to guide the movement path of the lower rod 570 so that the lower rod 570 can accurately contact the lower surface of the lower ring 160.

However, the outer diameter of the piston head 561 is formed larger than the diameter of the hole of the lower guide 580. Therefore, the lower piston 560 can move upward only until the piston head 561 contacts the lower surface of the lower guide 580. Accordingly, the lower guide 580 may also serve to limit the lower piston 560 from being excessively moved upward.

The lower length adjusting member 590 is formed at a specific height, and is detachably coupled around the hole at the lower surface of the lower guide 580.

When such a lower length adjusting member 590 is installed, the lower piston 560 can now move upwards only until the piston head 561 contacts the lower end of the lower length adjusting member 590. The lower the lower length adjusting member 590, the more the lower piston 560 can move upwards. On the other hand, the lower the lower length adjusting member 590, the lower the lower piston 560 can move upwards. will be.

Accordingly, a plurality of lower length adjustment members 590 having different heights can be provided, and the compression length can be easily adjusted by replacing and using the appropriate lower length adjustment member 590 as necessary.

Referring to FIG. 8 further, the carbon block compression mechanism 600 is disposed downstream (area I in the case of FIG. 4) than the raw material compression mechanism 500, so that the raw material of the outer mold 120 is heat-treated, that is, the carbon block It serves to compress.

To this end, the carbon block compression mechanism 600 includes an upper piston 610, an upper rod 620, a pressure ring 630, an upper guide 640, an upper length adjusting member 650, a lower piston 660, and a lower rod 670, a lower guide 680 and a lower length adjustment member 690.

However, these are the upper piston 510, the upper rod 520, the pressure ring 530, the upper guide 540 of the raw material compression mechanism 500 described with reference to Figure 7, the upper length adjustment member 550, the lower piston 560, the lower rod 570, the lower guide 580 and the lower length adjusting member 590 are substantially the same, and even if there are different parts, a person skilled in the art compresses the powdery raw material and compresses the solid carbon block. In response to this, it is of course only expected to be changed, so a redundant description thereof will be omitted.

Referring to FIG. 9 further, the carbon block ejection mechanism 700 is disposed downstream (section J in the case of FIG. 4) than the carbon block compression mechanism 600 to discharge and cut the carbon block from the outer mold 120. do.

To this end, the carbon block discharge mechanism 700 includes a piston 710, a rod 720, a guide 730, a manipulator (not shown), and a cutter 740.

The piston 710 is disposed below the jig module 100, and can be moved upward by, for example, a hydraulic cylinder or an actuator.

The rod 720 is coupled to the lower end (piston head) 711 of the piston 710 and moves together with the piston 710.

Accordingly, by moving the rod 720 upward and further moving upward while in contact with the lower surface of the lower ring 160, the carbon block can be discharged upward from the outer mold 120 through the lower ring 160.

The piston 710 and the rod 720 may be integrally formed together, or separately formed and coupled to each other.

The guide 730 is disposed above the piston head 711, and a hole is formed through which the rod 720 passes. Accordingly, the guide 730 may serve to guide the movement path of the rod 720 so that the rod 720 can accurately contact the lower surface of the lower ring 160.

However, the outer diameter of the piston head 711 is formed larger than the diameter of the hole of the guide 730. Therefore, the piston 710 can only move upwards until the piston head 711 contacts the upper surface of the guide 730. Accordingly, the guide 730 may also serve to limit the piston 710 from being excessively moved upward.

The manipulator and the cutter 740 are disposed above the jig module 100.

Accordingly, the manipulator grips and fixes the carbon block, and the cutter 740 cuts the lower portion of the carbon block at a preset point.

In the drawing, it is illustrated that the cutter 740 is installed as one, but if necessary, a plurality of cutters may be installed to cut the lower portion of the carbon block by radially moving together toward the center of the carbon block.

If the manipulator simply picks up the carbon block, the lower portion of the carbon block may be torn off due to adhesion between the carbon block and the lower ring 160, and the lower surface of the carbon block may be irregularly formed. Therefore, there is a problem that requires a subsequent process of separately processing the lower surface of the carbon block.

However, if the cutter 740 cuts the lower portion of the carbon block at a predetermined point, there is an advantage that the lower surface of the carbon block can be formed smoothly at all times.

Hereinafter, a method of manufacturing the carbon block will be described.

10 is a flowchart of a carbon block manufacturing method.

First, it is assumed that the outer mold 120 and the inner core 130 of the jig module 100 are heated to a predetermined temperature by the outer heater 140 and the inner heater 150 and maintained at that temperature.

When the jig module 100 reaches the raw material supply mechanism 300, the raw material supply mechanism 300 supplies raw materials to the external mold 120 (S1 ).

At this time, as mentioned above, the injection hole 310 of the raw material supply mechanism 300 starts to inject the raw material in a state inserted into the external mold 120 at a preset depth, and gradually moves upward as the raw material is injected. have.

However, in this step (S1), the raw material supply mechanism 300 supplies only a part of the amount of the raw material necessary for manufacturing one carbon block to the outer mold 120.

Next, based on FIG. 4, when the transfer mechanism 200 transfers the jig module 100 clockwise, and the jig module 100 reaches the preliminary raw material compression mechanism 400, the preliminary raw material compression mechanism ( 400) primarily compresses the raw material of the outer mold 120 (S2).

Thereafter, the transfer mechanism 200 transfers the jig module 100 counterclockwise.

Accordingly, when the jig module 100 reaches the raw material supply mechanism 300 again, the raw material supply mechanism 300 even supplies the rest of the amount of raw materials required for manufacturing one carbon block to the outer mold 120 ( S3).

Next, when the feed mechanism 200 transfers the jig module 100 in the clockwise direction, when the jig module 100 passes through the preliminary raw material compression mechanism 400 and reaches the raw material compression mechanism 500, the raw material compression mechanism 500 is to compress the raw material of the outer mold 120 secondary (S4).

At this time, the raw material of the outer mold 120 may be compressed downward using the pressure ring 530, and the raw material of the outer mold 120 may be compressed upward using the lower ring 160. According to this, the raw material can be compressed as a whole.

If the raw material supply mechanism 300 attempts to supply the entire amount of raw materials necessary for manufacturing one carbon block to the outer mold 120 at once, the volume (height) of the outer mold 120 must be very large. There is a spatial disadvantage.

However, if the amount of the raw material is divided into two and the primary raw material is compressed after the primary raw material is supplied and the secondary raw material is compressed after the secondary raw material is supplied, the height of the external mold 120 can be reduced.

More specifically, when the primary raw material is supplied, 60% to 80% of the total height of the inner space of the outer mold 120 may be supplied. For example, if the total height of the inner space of the outer mold 120 is L and the height of the raw material is L'after supplying the primary raw material, 0.6L≤L'≤0.8L may be satisfied.

If the raw material is supplied with too few raw materials when supplying the first raw material, the supply of the second raw material must supply relatively more raw materials, and the height of the outer mold 120 must be increased as much, so the height of the outer mold 120 is sufficiently increased. There is a problem that cannot be reduced.

On the other hand, when the outer mold 120 and the inner core 130 are already heated by the outer heater 140 and the inner heater 150, as described above, the raw material is the outer circumferential surface of the outer mold 120 and the inner core 130 ) Can adhere to the inner peripheral surface. Accordingly, if the raw material is supplied too much during the supply of the first raw material, there is a problem that the raw material may overflow out of the external mold 120 before supplying all the predetermined amounts of the raw material.

Therefore, if it satisfies 0.6L≤L'≤0.8L, it is possible to appropriately reduce the height of the outer mold 120 while preventing the raw material from overflowing the outer mold 120 as much as possible.

In addition, when the primary raw material is compressed, it may be compressed by 60% to 80% of the height (L') of the raw material after supplying the primary raw material. For example, if the height of the raw material after compression of the primary raw material is L", 0.6L'≤L"≤0.8L' may be satisfied.

If the raw material is compressed too little when the primary raw material is compressed, the space for supplying the raw material when supplying the secondary raw material is relatively insufficient. This means that the height of the outer mold 120 should be larger.

Conversely, if the raw material is compressed too much when the raw material is compressed, the density is too high to show the desired filter characteristics, and in the final carbon block, the portion by the primary raw material compression and the portion by the secondary raw material compression are mutually exclusive. There is a problem of having different filter characteristics.

Therefore, if 0.6L'≤L"≤0.8L' is satisfied, it is possible to adequately secure a space for supplying the raw material when supplying the second raw material, but also exhibit uniform filter characteristics as a whole.

Of course, if necessary, the amount of the raw material may be divided into three or more, and the third raw material may be compressed after the third raw material is supplied.

Thereafter, the transfer mechanism 200 transfers the jig module 100 clockwise toward the carbon block compression mechanism 600.

At this time, as described above, the jig module 100 receives power from the external power supply through the brush 290 by contacting the terminal 180 with the brush 290 to operate the external heater 140, the internal heater 150, and the like. can do.

In addition, in the process of the jig module 100 moving from the raw material compression mechanism 500 to the carbon block compression mechanism 600, the raw material of the outer mold 120 is naturally heat-treated to be made of carbon blocks.

When the jig module 100 reaches the carbon block compression mechanism 600 (section I in FIG. 4 ), the carbon block compression mechanism 600 compresses the carbon block of the outer mold 120 (S5).

This is because even if the raw material of the outer mold 120 is compressed to the desired length by the raw material compression mechanism 500, it expands while being heat treated thereafter, and the carbon block may be slightly longer than the desired length. Therefore, the carbon block of the outer mold 120 can be adjusted to a desired length by finally compressing.

At this time, the carbon block of the outer mold 120 may be compressed downward by using the pressing ring 630, and the carbon block of the outer mold 120 may be compressed upward by using the lower ring 160.

Next, when the transfer mechanism 200 transfers the jig module 100 in the clockwise direction, when the jig module 100 reaches the carbon block discharge mechanism 700 (section J in FIG. 4 ), the carbon block discharge mechanism ( 700) discharges the carbon block from the outer mold 120 (S6).

Accordingly, the manipulator grips the carbon block, and the cutter 740 cuts the lower end of the carbon block (S7), whereby the carbon block can be finally completed.

Subsequently, when the transfer mechanism 200 transfers the jig module 100 in the clockwise direction, when the jig module 100 reaches the raw material supply mechanism 300 (section B in FIG. 4 ), the aforementioned steps are continuously repeated. do.

The above-described jig module 100, a carbon block manufacturing apparatus and a carbon block manufacturing method including the jig module 100, a jig module, a carbon block manufacturing apparatus and a carbon block including a jig module according to various embodiments of the present invention It is just one of the manufacturing methods.

For example, in the above, one jig module 100 has been described for convenience of understanding. However, while the plurality of jig modules 100 are moved by the transfer mechanism 200, the raw material supply mechanism 300 and the preliminary raw material compression mechanism ( 400), the raw material compression mechanism 500, the carbon block compression mechanism 600, and the carbon block discharge mechanism 700 may perform the aforementioned roles for each jig module 100 in succession.

In addition, the distance between the raw material supply mechanism 300 and the preliminary raw material compression mechanism 400, the distance between the main raw material compression mechanism 500 and the carbon block compression mechanism 600, etc. may be appropriately changed as necessary.

In particular, the raw material supply mechanism 300 and the preliminary raw material compression mechanism 400 are adjacent to each other in order to shorten a series of time leading to the primary raw material supply (S1), primary raw material compression (S2), and secondary raw material supply (S3). It can be arranged, or can be integrated into a single device as needed. Alternatively, the preliminary raw material compression mechanism 400 is omitted, and the main raw material compression mechanism 500 may perform both primary raw material compression (S2) and secondary raw material compression (S4).

As described above, the technical spirit of the present invention is not limited to the above embodiments, and as described in the claims, there will be a technical spirit to the extent that a person having ordinary knowledge in the technical field to which the present invention pertains can easily change.

Claims (8)

A jig module for a carbon block manufacturing apparatus movable by a transport mechanism,
Base,
An external mold installed on one surface of the base and defining an external shape of the carbon block,
An external heater for heating the external mold,
External temperature sensor for measuring the temperature of the external mold,
A lower plate serving as a floor to the inner space of the outer mold, and
A jig module for a carbon block manufacturing apparatus including a temperature control panel that controls the external heater so that the temperature of the external mold maintains a preset range. According to claim 1,
A jig module for a carbon block manufacturing apparatus which is provided in a plurality of the external heaters and arranged at predetermined intervals along the height direction of the external mold. According to claim 1,
The lower plate is installed to be movable up and down relative to the outer mold,
A jig module for a carbon block manufacturing apparatus having a hole through which a compression mechanism for pressing the lower plate upward from the lower side of the base passes through the base. According to claim 1,
It is installed on one surface of the base, and is disposed inside the outer mold and includes an inner core defining an inner shape of the carbon block,
The lower plate has an outer diameter corresponding to the inner diameter of the outer mold and an inner diameter formed in an annular shape corresponding to the outer diameter of the inner core, for the carbon block manufacturing apparatus installed to be movable up and down relative to the outer mold and the inner core Jig module. According to claim 4,
An inner heater for heating the inner core and
It includes an internal temperature sensor for measuring the temperature of the inner core,
The temperature control panel is a jig module for a carbon block manufacturing apparatus for controlling the internal heater so that the temperature of the inner core maintains a preset range. The method of claim 5,
The inner heater is a jig module for a carbon block manufacturing apparatus embedded in the body of the inner core. The method of claim 5,
A jig module for a carbon block manufacturing apparatus, which is installed in a plurality of the inner heaters and arranged at predetermined intervals along the height direction of the inner core. According to claim 1,
A jig module for a carbon block manufacturing apparatus made of a conductive material and installed on the other surface of the base, and including a terminal for receiving power.

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