KR100811582B1 - Apparatus for molding activated carbon - Google Patents

Abstract

The present invention is a molding apparatus in consideration of the basic characteristics of activated carbon having low spreadability due to lack of lubrication. A raw material supply unit to be supplied; The raw material of the activated carbon is supplied from the raw material supply unit, and the compression distribution by the bypass structure induces even spreading of the raw material to prevent the compression distribution from being biased in one part, and preserves the pore structure of the activated carbon raw material in the tissue. A compression molding unit for achieving product formation having high breathability and adsorption property; An on-loading unit configured to load a molded product of activated carbon processed through the compression molding unit onto an upper surface of an empty pallet and to transfer a pallet loaded with the molded product onto a conveyor; It is characterized in that the technical configuration to include the oil / pneumatic supply unit for supplying by controlling the hydraulic pressure and pneumatic pressure required for the operation of each unit.

According to the present invention, it is possible to arbitrarily adjust the filling amount when supplying the raw material into the device, so that it is possible to simultaneously fill a large number of products, thereby improving productivity, and uniformity in the molded product according to the prevention of the bias of the compression distribution during the compression molding of the raw material. It has a density formation and thereby strength and durability, and has a very useful effect of making a molding deodorant excellent in deodorizing effect.

Description

Activated Carbon Forming Equipment {APPARATUS FOR MOLDING ACTIVATED CARBON}

1 is a view showing the pore structure of a general activated carbon.

Figure 2 is a front view showing the activated carbon forming apparatus according to the present invention.

Figure 3 is a plan view showing an activated carbon forming apparatus according to the present invention.

Figure 4 is a side view showing an activated carbon forming apparatus according to the present invention.

5A and 5B are conceptual views shown for explaining the raw material supply unit side filling means in the apparatus of the present invention.

Figure 5c is a plan view showing the raw material supply unit side filling member in the apparatus of the present invention.

Figure 6 is a detail view of the main portion shown to explain the compression molding unit in the apparatus of the present invention.

7a and 7b is a bottom perspective view and a cross-sectional view showing an example of the activated carbon deodorizing product produced by the apparatus of the present invention.

8a and 8b are a perspective view and a cross-sectional view showing another example of the activated carbon deodorizing product produced by the apparatus of the present invention.

Explanation of symbols on the main parts of the drawings

100: forming apparatus 101: base

102: pallet 103: conveyor

110: raw material supply unit 111: hopper

112: filling means 112a: rotating drum

112a-1: Filling groove 112b: External drum

112c: scraper 113: vibration motor

114: filling member 114a: filling hole

120: compression molding unit 121: lower mold

122: upper mold 122a: fixed top plate

122a-1: forming pin 122b: movable lower plate

130: on-loading unit 131: vacuum adsorption means

132: pallet seating portion 133: front / reverse cylinder

134: residue removal member 135: pallet transfer chuck

BPH1: Bypass Hole

The present invention relates to a molding apparatus for molding the activated carbon raw material into a certain shape and structure to produce a product, and more specifically, to prevent the compression distribution and to form a uniform density of activated carbon in consideration of the characteristics of activated carbon having poor spreadability due to lack of lubricity. The present invention relates to an activated carbon molding apparatus capable of producing activated carbon deodorant, which enables the molded products of activated carbon to have very excellent strength and durability, and improves breathability and adsorptivity in a molding structure, thereby exhibiting an excellent deodorizing effect.

In general, activated carbon is an aggregate of amorphous carbon having a large internal surface area with well developed micropores and connected to numerous micropores, and is a physically / chemically stable nonpolar adsorbent. It is a material widely used in the field of decolorization, deodorization, purification, recovery, separation and collection.

Adsorption properties of such activated carbon are different depending on the pore structure and the inner surface area (specific surface area). As shown in FIG. 1, the normal pore structure of activated carbon is 20 microns or less with a micropore having a diameter of 20 μs or less. It is composed of three systems of transition-pore having a diameter of and Macro-pore having a diameter of 1000 Å or more, and a typical inner surface area forms about 500 m 2 / g to 1,500 m 2 / g. Here, the micro-pore is the final stage of adsorption of the adsorbent and the macro-pore and transitional-pore serve as a passage for sending the adsorbed material to the micro-pore.

On the other hand, activated carbon is in the form of a powder to be commercialized according to molding, activated carbon has a characteristic that does not easily spread due to lack of lubricity. Due to these characteristics, there are many difficulties in forming activated carbon, such as compression distribution being concentrated in one part through general compression molding, and for this reason, strength and durability in the molded products are considerably weak.

In addition, many attempts have been made to form a product through heat treatment, but a binder of CPE (Chlorinated Polyethylene) is used to bond raw materials to activated carbon, which is a powder. Was produced.

By the way, in applying the heat treatment molding method as described above, the binder of the CPE (melting point 150 ℃) is melted by the heat of 150 ℃ exhibits a function to enable the smooth adhesion between the raw materials, but the activity of the binder according to the melting As a result, the binder material melted into the pores of activated carbon flows to form pores, thereby preventing the pores, thereby acting as a factor that inhibits basic adsorption and breathability of activated carbon.

In other words, there has not been a compression molding method of activated carbon molding apparatus considering the basic characteristics of activated carbon, and existing activated carbon molded products have a weak strength and durability, and deodorization effect is caused by weakness of breathability and adsorption in activated carbon molded products. There was a problem with the lack of functionality.

In addition, conventionally, raw materials of activated carbon were introduced into the apparatus by using a large supply and a small supply method. This method is a 1: 1 response method in which a large amount of supply cannot be filled at the same time. In order to simultaneously charge the installation cost and installation area of the facility is excessive, it has a problem that decreases the efficiency of the device.

SUMMARY OF THE INVENTION An object of the present invention is to provide an activated carbon molding apparatus of a compression molding method in consideration of the basic characteristics of activated carbon having low spreadability due to lack of lubrication.

In addition, the present invention is to enable not only to greatly improve the efficiency of using the device according to the compression molding of activated carbon, but also to improve productivity.

Furthermore, the present invention allows to adjust the filling amount at the time of supplying the activated carbon raw material in the device arbitrarily at the same time, and to prevent the compressed distribution of activated carbon from being biased in one part during compression molding through the molding mold It is to enable uniform density formation of activated carbon in the molded article, as well as to provide excellent strength and durability.

In addition, the present invention is to increase the air permeability and adsorption of the tissue in the molded product by making it possible to preserve the pore structure of the activated carbon as a raw material as much as possible to form a molding deodorant excellent in deodorizing effect.

The present invention for achieving the above object is a raw material supply unit for controlling the discharge amount of the powdered activated carbon raw material, but at the same time a plurality of simultaneous filling and to supply the activated activated carbon raw material to the following compression molding unit; The raw material of the activated carbon is supplied from the raw material supply unit, and the compression distribution by the bypass structure induces even spreading of the raw material to prevent the compression distribution from being biased in one part, and preserves the pore structure of the activated carbon raw material in the tissue. A compression molding unit for achieving product molding having high breathability and adsorption property; An on-loading unit configured to load a molded product of activated carbon processed through the compression molding unit onto an upper surface of an empty pallet and to transfer a pallet loaded with the molded product onto a conveyor; It characterized in that it comprises a hydraulic / pneumatic supply unit to be supplied by controlling the hydraulic pressure and pneumatic pressure required for the operation of each unit.

The raw material supply unit includes a drum roller-type filling means for enabling a quantitative discharge of the raw material but allowing a plurality of simultaneous filling at a time, wherein the filling means is rotatably installed on the lower side of the hopper and is fixed on an outer circumferential surface thereof. A cylindrical rotating drum having a plurality of raw material filling grooves disposed diagonally at intervals; An outer drum which closely surrounds the outer circumferential surface of the rotating drum to form an outlet for discharging the raw material and discharges the raw material filled in the raw material filling groove of the rotating drum without being lost; It characterized in that the scraper to enable the quantitative supply of the raw material by cutting the upper surface of the raw material filled in the raw material filling groove of the rotating drum.

The compression molding unit is configured to prevent a bias of the compression distribution of the non-lubricated activated carbon by having an upper mold and a lower mold having a bypass structure protruding the forming pins, rather than the compression method of the female and male in general. The upper mold is characterized in that it is configured to have a temperature condition of 90 ~ 100 ℃ and the lower mold 100 ~ 115 ℃, a pressure condition of 120 ~ 250kg / cm2, and a time condition of 10 ~ 20 seconds.

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

2 is a front view showing an activated carbon forming apparatus according to the present invention, Figure 3 is a plan view showing an activated carbon forming apparatus according to the present invention, Figure 4 is a side view showing an activated carbon forming apparatus according to the present invention, Figures 5a and 5b Is a conceptual diagram shown to explain the raw material supply unit side filling means in the apparatus of the present invention, Figure 5c is a plan view showing the raw material supply unit side filling member in the apparatus of the present invention, Figure 6 is a device of the present invention 7A and 7B are a perspective view and a cross-sectional view showing an example of an activated carbon deodorizing product manufactured by the apparatus of the present invention, and FIGS. 8A and 8B are the apparatus of the present invention. It is a perspective view and a cross-sectional view showing another example of the activated carbon deodorizing product produced by.

As shown in Figures 2 to 6, the activated carbon forming apparatus 100 according to the present invention is to control / discharge the filling amount of the powdered activated carbon raw material to enable a plurality of simultaneous filling at a time and compression molding the activated carbon raw material to the following A raw material supply unit 110 to be supplied to the unit 120; The raw material of the activated carbon is supplied from the raw material supply unit 110, and the compression distribution by the bypass (bypass) structure to induce even spreading of the raw material to prevent the compression distribution from being biased in one portion, the inside of the tissue of the activated carbon raw material Compression molding unit 120 to form a product that maintains the pore structure to maintain breathability and adsorptivity; The molded product of activated carbon formed by the compression molding unit 120 is loaded onto the upper surface of the empty pallet 102 and the pallet 102 loaded with the molded product onto the conveyor 103. An on loading unit 130 for transferring; It consists of a configuration including a hydraulic / pneumatic supply unit 140 to be supplied by controlling the hydraulic pressure and pneumatic pressure required for the operation of each unit (110 ~ 130).

In addition, it is possible to set / change the molding pressure, molding temperature, and molding time of the compression molding unit 120, display the current operating conditions, and program the operation of each unit 110 to 140. It consists of a configuration including a control panel (not shown) for controlling.

The raw material supply unit 110 is a hopper 111 for injecting the activated carbon powder raw material, the drum is installed in conjunction with the lower portion of the hopper 111 to enable the quantitative discharge of the raw material but at the same time a plurality of simultaneous filling It is disposed in the roller filling means 112, the hopper 111 and the vibration motor 113 to exert the distribution effect of the raw material through the vibration during the filling of the raw material, and is disposed below the hopper 111 A plurality of filling members 114 having a filling hole 114a formed so as to temporarily fill a quantity of discharged material dispensed / discharged through the filling means 112, and are disposed below the filling member 114. Moving the supporting member 115 supporting the bottom surface to enable temporary filling of the raw material to the 114a and the filling member 114 supported by the supporting member 115 onto the compression molding unit 120. By the moving cylinder 116 and the moving cylinder 116 Axis configuration causes the filling member 114, side filling material moves onto the forming unit 120 to the material supply cylinder 117 to be supplied into the compression-molding unit (120).

At this time, the filling hole 114a of the filling member 114 forms an upper inclined structure 114a-1 to smoothly induce the inflow of the filled raw material, but forms an extension groove 114a-2 in all directions to supply the raw material. It is preferable to be configured to facilitate the peripheral supply, and the planar structure is to form a substantially rounded quadrangular structure.

In addition, the support member 115 is provided with a through hole (not shown) disposed to be offset from the filling hole 114a of the filling member 114, and is supported by the raw material supply cylinder 117. The raw material is supplied into the compression molding unit 120 by making the through hole coincide with the filling hole through the striking.

The filling means 112 is installed to be rotatable in the lower side of the hopper 111 and the cylindrical rotating drum (112a) formed a plurality of raw material filling grooves (112a-1) arranged diagonally at a predetermined interval on the outer peripheral surface (112a) ) And the outer circumferential surface of the rotating drum (112a) in close contact with each other to form a discharge outlet (112b-1) for discharging the raw material filled in the raw material filling groove (112a-1) of the rotating drum (112a). External drum (112b) to be discharged to the outside without, and the scraper (112c) to cut the upper surface of the raw material filled in the raw material filling groove (112a-1) of the rotating drum (112a) to enable the quantitative supply of raw materials To be.

The compression molding unit 120 receives the raw material from the filling member 114 of the raw material supply unit 110 into the female molding die 121a and is installed on the base 101 by the operation of the lower cylinder 123. The lower mold 121, which is moved up and down linearly by the guide member 124, and the fixed upper plate which is disposed above the lower mold 121 and protrudes a plurality of forming pins 122a-1 on the lower surface thereof. 122a) and a male molding frame 122b-1 positioned below the upper plate 122a and formed to allow linear movement up and down by the upper cylinder 125 and forming a bypass hole BPH1 on the lower surface. The upper mold 122 having a movable lower plate 122b having the upper portion 122 is configured.

In this case, the forming pins 122a-1 and the bypass holes BPH1 are formed on the same position line as well as the same number.

The forming pins 122a-1 taper the lower end portion A toward the lower direction, and are sharpened, but before / after the force of compressing the raw material by processing to have a four-direction inclined surface structure in front / rear / left / right. It is desirable to be configured to act in all directions of / left / right. This, in addition to the pressure acting as a center, induces pressure distribution to all sides, thus enabling uniform density formation during compression molding of raw materials and providing excellent strength and durability to molded products.

The on-loading unit 130 is vacuum-molded through the compression molding unit 120 so as to load the product having a predetermined shape (loading) vacuum adsorption 102 to the vacuum suction but moving the pallet seating portion ( The vacuum suction means 131 to be seated / fixed on the 132 and the pallet seating portion 132 are moved under the upper mold 122 of the compression molding unit 120 to form a molded product on the pallet 102. It is possible to simultaneously load the residue removal member 134 to remove the remaining material residues left after molding in the female molding die (121a) of the lower mold (121) of the lower mold 121 to move simultaneously to the compression molding unit 120 The reverse cylinder 133 and the pallet 102 loaded with the molded product are then grasped and moved to the center so that the pallet transfer chuck 135 seats the pallet 102 on the conveyor 103.

Here, the vacuum adsorption means 131 and the pallet transfer chuck 135 is preferably configured to perform the operation of the left / right movement and the up / down movement at the same time to improve the efficiency of the device operation.

In addition, the empty pallet 102 is to be supplied through the pallet supply unit 136, but the pallet (102) is pushed upward through the upper pushing (pushing) operation through the cylinder (136a) to always lift the pallet at a constant position ( 102) to be able to supply.

Furthermore, each unit (110 ~ 140) of the present invention is provided with a plurality of motion detection sensors (not shown) for the accuracy and efficiency of operation to be configured to immediately stop the operation of the device if any abnormality occurs anywhere do.

Referring to the operation of the activated carbon forming apparatus 100 according to the present invention made of such a configuration as follows.

The powdered raw material of activated carbon introduced into the hopper 111 is discharged quantitatively by adjusting the rotation amount of the filling means 112 to be filled into the filling hole 114a of the filling member 114 disposed below the hopper 111. At this time, the vibration motor 113 mounted on the hopper 111 to exhibit the distribution effect of the raw material by forming a vibration on the hopper 111. Here, the raw material introduced into the hopper 111 is filled into the raw material filling groove 112a-1 of the rotating drum 112a and is rotated while the upper surface is shaved by the scraper 112c to achieve quantitative filling. A plurality of filling members 114 are formed at the same time through the outlet 112b-1, and the drum roller method is configured to support the number of formation of the raw material filling grooves 112a-1. It is possible to provide a large number of supplies, but the amount of filling can be arbitrarily adjusted, so that mass production and productivity can be improved along with supply of quantitative raw materials.

When the filling of the raw material to the filling member 114, the moving cylinder 116 is advanced to the filling member 114 disposed on the support member 115 on the lower mold 121 of the compression molding unit 200 The position is moved, and the filling hole 114a of the filling member 114 and the through hole of the supporting member 115 which are shifted by hitting the supporting member 115 through the raw material supply cylinder 117 are filled. The raw material temporarily filled in the hole 114a is supplied into the female molding die 121a of the lower mold 121. At this time, the raw material in the filling hole (114a) is distributed / supplied to the female molding die (121a) by the vibration caused by the strike, in particular the raw material to be supplied is the structure of the filling hole (114a) formed on all four sides extending grooves (114a-2) By spreading to the periphery instead of the centralized by so as to be evenly supplied inside the female mold (121a).

Further, while the raw material is supplied into the lower mold 121, the vacuum adsorption means 131 on the side of the onloading unit 130 vacuum-adsorbs the empty pallet 102 from the pallet supply part 136, but moves the pallet through the center movement. Palette 102 is seated / secured on 132.

When the supply of the raw material is completed into the forming mold 121a of the lower mold 121, the filling member 114 is returned to the lower side of the hopper 111 by the backward operation of the moving cylinder 116, and the compression molding unit ( The lower mold 121 performs an upward movement by the lower cylinder 123 associated with the lower mold 121, and moves upward by riding the guide member 124, and moves the lower mold 122b of the upper mold 122. It moves until it moves in close contact with this fixed upper plate 122a. Here, the upper mold 122 and the lower mold 121 starts molding by applying pressure to the raw material supplied by the matching of the protruding male molding die 122b-1 and the recessed female molding die 121a. As shown in FIGS. 7A and 7B, the forming pins 122a-1 protrudingly arranged on the fixed upper plate 122a pass through the bypass hole BPH1 formed in the male mold 122b-1. The through-air vent 210 for breathability is formed in the molded product. At this time, the forming pin 122a-1 forms the vent 210 through compression, and each of the forming pins protrudingly arranged passes through the bypass hole BPH1 and uses the raw material supplied into the lower mold 121. Dispersion is arranged in all directions of front, rear, left, and right, and it prevents bias of compression distribution through distribution of raw materials. Therefore, it enables not only uniform density formation but also production of activated carbon molded products with excellent strength and durability after molding. To be able.

In addition, the compression molding of the raw material under the conditions of 90 ~ 100 ℃ of the upper mold 122 side and 100 ~ 115 ℃ of the lower mold 121 side, pressure of 120 ~ 250kg / cm2, and the time of 10 ~ 20 seconds In the present invention, by performing the molding at a temperature lower than the melting point (150 ℃) of the binder (CPE) for the adhesion function between the raw materials, only a slight insignificant tissue change to save the functionality of the binder in the activated carbon raw material Induction and prevention of melting of the binder allow preservation treatment of the basic pore structure of the activated carbon even after the formation of the activated carbon. Accordingly, unlike the existing one will act to greatly increase the air permeability and adsorption in the molded product of activated carbon.

In addition, during the molding operation on the compression molding unit 120, the raw material supply unit 110 side to perform the operation of filling the raw material in the filling member 114 at the same time.

When the compression molding is completed, the lower cylinder 123 is operated to move the lower mold 121 to the lower side, and the empty pallet 102 is fixed by the forward operation of the forward / backward cylinder 133 on the on-loading unit 130 side. The pallet seating portion 132 is placed under the upper mold 122 in the compression molding unit 120 and at the same time, the residue of the raw material remaining in the female molding die 121a of the lower mold 121 is removed. Through 134).

Here, when the empty pallet 102 is disposed in the compression molding unit 120, the upper mold 122 by operating the upper cylinder 125 associated with the movable lower plate 122b to move the lower plate 122b downward. The finished molded product secured to the bed is separated so as to be loaded onto the empty pallet 102.

The reverse operation of the forward / reverse cylinder 133 returns the pallet 102 and the pallet seating part 132 loaded with the molded product to their original positions, and then lowers the pallet transfer chuck 135 to grasp the pallet and move the center. The pallet loaded with the molded product is seated on the conveyor 103. At this time, when the pallet 102 is mounted through the pallet transfer chuck 135, the vacuum suction means 131 vacuum-adsorbs the empty pallet 102 from the pallet supply unit 136 in a simultaneous operation, and the pallet transfer chuck 135 is conveyed. The empty pallet, which has been vacuum-adsorbed, is seated on the pallet seating portion 132 in a simultaneous motion while seating the loading pallet on the 103.

On the other hand, the activated carbon forming apparatus 100 of the present invention having the configuration and action as described above is to achieve the simultaneous operation through the program control on each unit to improve the efficiency and productivity of the use and operation of the device, Figure 7a and As shown in FIG. 7B, it is possible to produce activated carbon deodorant product 200 having through vents 210 arranged in a straight line up and down in the same arrangement. At this time, the vent 210, the upper side 211 is to form a substantially circular and the lower side 212 is to form a square.

In addition, as shown in FIGS. 8A and 8B, a plurality of circular vents 311 are formed through the upper body 310 and the rectangular through-holes are formed so as to be arranged to be offset to the circular vent 311 of the upper body 310 ( It is also possible to produce an activated carbon molded product 300 having an inner hollow 330 formed between the upper body 310 and the lower body 320 but having a coupling configuration of the lower body 320 having a 321.

Therefore, the molding apparatus of the present invention enables the molding of a deodorizing product having a very excellent strength and durability in a compression molding method and a uniform density configuration.

In addition, according to the activated carbon forming apparatus 100 according to the compression molding method according to the invention, not only to form a specific surface area of at least 1000m2 / g up to 3000m2 / g, but also to form an adsorption amount of 50 ~ 60% per unit weight As a result, it is possible to produce an extended product of the adsorption rate and the adsorption rate, which can exhibit an improved effect of the deodorizing function.

On the other hand, the activated carbon forming apparatus according to the present invention has been described with reference to the specific embodiments and the accompanying drawings as described above, but is not particularly limited thereto, the technical configuration that is variously modified by those skilled in the art the present invention It will be attributed to the description and the interpretation of the claims.

In particular, the present invention can be referred to as the invention of the apparatus having the versatility of the application range that can be usefully utilized not only for the shaping of activated carbon, but also for the molding of all raw materials made of powder as the above-described functionality.

As described above, according to the activated carbon forming apparatus according to the present invention, it is possible to arbitrarily adjust the filling amount when supplying the raw materials into the apparatus, and at the same time, to enable a plurality of fillings, and molding according to the prevention of the bias of the compression distribution during the compression molding of the raw materials. It is very useful to make a deodorizing product having excellent deodorizing effect by making uniform density formation in the product, and thereby having strength and durability, and improving the structure considering the basic characteristics of activated carbon which is poor in lubrication. Exert.

In addition, it is possible not only to greatly improve the efficiency of using and operating the device according to compression molding of activated carbon, but also to improve mass production and productivity.

Furthermore, by applying the compression molding method to preserve the pore structure of the activated carbon as a raw material as much as possible even during molding, it is possible to produce by increasing the breathability and adsorption of the tissue in the molded product.

Claims (8)

A raw material supply unit which controls / discharges the filling amount of the powdered activated carbon raw material but enables a plurality of simultaneous filling at once and supplies the filled activated carbon raw material to the next compression molding unit; The raw material of the activated carbon is supplied from the raw material supply unit, and the compression distribution by the bypass structure induces even spreading of the raw material to prevent the compression distribution from being biased in one part, and preserves the pore structure of the activated carbon raw material in the tissue. A compression molding unit for forming a product that maintains breathability and adsorptivity; An on-loading unit configured to load a molded product of activated carbon processed through the compression molding unit onto an upper surface of an empty pallet and to transfer a pallet loaded with the molded product onto a conveyor; Activated carbon forming apparatus characterized in that it comprises a hydraulic / pneumatic supply unit for controlling the supplied hydraulic pressure and pneumatic operation of each unit. The method of claim 1, The raw material supply unit and the hopper for injecting the powder raw material; A drum roller-type filling means installed in a lower portion of the hopper to enable quantitative discharge of raw materials and to enable a plurality of simultaneous filling at once; A vibration pump mounted to the hopper and exerting a distribution effect of the raw material through vibration when the raw material is filled; A plurality of filling members disposed below the hopper and configured to fill a filling hole to temporarily fill a quantity of discharged material dispensed / discharged through the filling means; A supporting member disposed below the filling member and supporting the bottom surface of the filling hole to temporarily fill the filling hole; A moving cylinder for moving the filling member supported by the supporting member onto the compression molding unit; Activated carbon forming apparatus, characterized in that the raw material supply cylinder for supplying the filling member side filling material moved on the compression molding unit by the moving cylinder into the compression molding unit through the blow. The method of claim 2, The filling means is provided with a cylindrical rotating drum rotatably installed on the lower side of the hopper and formed with a plurality of raw material filling grooves arranged at an interval on the outer circumferential surface; An outer drum which closely surrounds the outer circumferential surface of the rotating drum to form an outlet for discharging the raw material and discharges the raw material filled in the raw material filling groove of the rotating drum without being lost; Activated charcoal molding apparatus comprising a scraper to cut the upper surface of the raw material filled in the raw material filling groove of the rotating drum to enable the quantitative supply of the raw material. The method of claim 2, The filling hole of the filling member is formed to have an upper inclined structure and further formed in all four directions extending grooves formed activated carbon forming apparatus, characterized in that the planar structure has a rounded rectangular structure. The method of claim 1, The compression molding unit includes a lower mold which receives the raw material from the raw material supply unit into the molding die of the female and moves linearly up / down by the guide member placed on the base by the operation of the lower cylinder; A fixed upper plate disposed above the lower mold and protrudingly arranged with a plurality of forming pins on the lower surface thereof, and positioned below the upper plate to allow linear movement of the upper and lower sides by the upper cylinder, and forming a bypass hole on the lower surface. Activated carbon forming apparatus characterized in that the upper mold having a movable lower plate having a male mold. The method of claim 5, wherein The plurality of forming pins protruding from the fixed top plate taper the lower end toward the lower side, and have a four-direction inclined structure in front, rear, left, and right to compress the raw material in all directions. Activated carbon molding apparatus, characterized in that configured to act. The method of claim 5, wherein The compression molding unit is an activated carbon forming apparatus, characterized in that formed at the temperature of the upper mold 90 ~ 100 ℃ and the lower mold 100 ~ 115 ℃, the pressure of 120 ~ 250kg / cm2, the molding conditions for a time of 10 ~ 20 seconds . The method of claim 1, The on-loading unit includes a vacuum suction means for vacuum-adsorbing an empty pallet for loading a product having a predetermined shape, which is compression molded through the compression molding unit, to be moved / secured on the pallet seating unit by moving the center; The pallet seating portion and the residue removal member for removing the residue left after molding in the compression molding unit are simultaneously moved into the compression molding unit to enable loading processing of the molded product onto the pallet and at the same time, the residue Front and back cylinders to remove the; Activated carbon forming apparatus comprising a pallet transfer chuck for holding the pallet with the molded product loaded and then moving to the center to seat the pallet on the conveyor.

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