KR20220042871A - Apparatus for manufacturing deodorant block - Google Patents

Abstract

The present invention relates to an apparatus for molding a deodorant block, including: a base frame; a lower mold unit mounted on the top surface of the base frame; a powder supplying unit provided at one side of the base frame and configured to supply powder to be processed to the mold of the lower mold unit, while reciprocating toward the lower mold unit; a cleaning unit provided at the other side of the base frame and configured to clean the mold of the lower mold unit, while reciprocating toward the lower mold unit; an upper mold unit disposed at the upper side of the lower mold unit and configured to perform compression molding of the powder filled in the mold of the lower mold unit, while moving in the longitudinal direction; and a heating unit disposed between the powder supplying unit and the cleaning unit and configured to heat the molded powder product of the lower mold unit compressed by the upper mold unit, while reciprocating toward the lower mold unit. According to the present invention, it is possible to heat and compress powder to be processed, including activated carbon, at a uniform temperature under uniform pressure to mold a deodorant block and to maximize the heat efficiency.

Description

Deodorizing material block forming device {APPARATUS FOR MANUFACTURING DEODORANT BLOCK}

The present invention relates to a deodorizing material block forming apparatus.

In general, the freezer compartment of a refrigerator freezes food below the freezing point to store food, but the refrigerator compartment stores food at a low temperature above the freezing point, and the food stored in the refrigerator compartment has a strong inherent odor, such as boiled fish, kimchi, cheonggukjang, salted fish, etc. When food is stored for a long time, odor is generated from the food. For this reason, whenever the user opens the door to take out food from the refrigerating compartment of the refrigerator, the smell escapes to the outside, causing discomfort to the user and spreading the smell around the refrigerator. In order to solve such a problem, a deodorant is provided in the refrigerator compartment of the refrigerator to remove odors generated during storage of food.

As a deodorant for removing odors from refrigerators, a deodorant containing activated carbon as a main component is most widely used. Activated carbon is an aggregate of amorphous carbon that has a large internal surface area with well-developed micropores and is connected by passages between countless micropores.

Republic of Korea Patent Publication No. 10-2007-0032212 (published on March 21, 2007) (hereinafter referred to as prior art) discloses an activated carbon molding apparatus for molding an activated carbon block by heating and pressing activated carbon powder. However, the molding apparatus disclosed in the prior art generates heat in the upper mold and the lower mold, respectively, to heat and pressurize the molded product formed by the upper mold and the lower mold, so the heat loss is large and the temperature is not uniformly transmitted to the inside of the molded product. There is a downside to not being able to.

It is an object of the present invention to provide a deodorizing material block molding apparatus for molding a deodorizing material block by heating and pressing a powder to be worked including activated carbon at a uniform temperature and pressure.

Another object of the present invention is to provide a deodorizing material block molding apparatus that maximizes thermal efficiency.

In order to achieve the above object, the base frame; a lower mold unit mounted on the upper surface of the base frame; a powder supply unit provided on one side of the base frame and reciprocating toward the lower mold unit to supply a powder to be worked on to the mold of the lower mold unit; a cleaning unit provided on the other side of the base frame to clean the mold of the lower mold unit while reciprocating toward the lower mold unit; an upper mold unit located above the lower mold unit and configured to pressurize the powder filled in the mold of the lower mold unit while moving up and down; and a heating unit positioned between the powder supply unit and the cleaning unit and configured to heat the powder compact of the lower mold unit pressurized by the upper mold unit while reciprocating toward the lower mold unit is provided. do.

The lower mold unit includes a base mold fixed to the base frame, a plurality of guide pins provided in a direction perpendicular to the edge of the base mold, and the guide pins are movably coupled to the upper surface of the base mold and placed on the upper surface of the base mold. and a first mold; It includes a second mold driving unit moving up and down, and the base mold preferably includes a base plate and hole forming pins provided on an upper surface of the base plate to form a plurality of groups.

The first mold includes a base plate, support blocks coupled to correspond to the hole-forming pin groups on the upper surface, and the support block and the base plate so that the hole-forming pins of the hole-forming pin group penetrate the support block. It may include pin insertion holes formed to pass through, and the second mold may include a base plate and molding holes provided in the base plate so that the support blocks are inserted through each.

The present invention fills the mold forming spaces of the lower mold unit with the target powder each containing the activated carbon powder, and the upper mold unit presses the powder respectively filled in the mold forming spaces of the lower mold unit for a set pressure and time. The target powder is pressurized to a uniform pressure, and then the heating unit heats the molded bodies in the mold forming spaces of the lower mold unit for a set temperature and time, so that the molded bodies are heated to a uniform temperature. In addition, the moldings are heated intensively by the heating unit to increase thermal efficiency.

In addition, in the present invention, when the lower mold unit includes a base mold with hole forming pins, a first mold with support blocks, and a second mold with forming holes, the support block of the first mold and the second mold Since the hole forming pins are located in the forming space formed by the forming hole of It is heated quickly and uniformly to the inside of the body, shortening the heating time, and uniformly heating to the inside of the molded body.

In addition, in the present invention, the cleaning unit cleans the pressurized molded body and the powder remaining in the mold in the mold forming space of the lower mold unit, and the heating unit heats the molded body to produce a deodorizing material block, so that the deodorizing material block oozes out coal powder or will prevent

1 is a front view showing an embodiment of a deodorizing material block forming apparatus according to the present invention;
2 is a plan view showing an example of a lower mold unit constituting an embodiment of the deodorizing material block molding apparatus according to the present invention;
3 is a front view showing an example of a lower mold unit constituting an embodiment of the deodorizing material block molding apparatus according to the present invention;
4 is a side view showing an example of a cleaning unit constituting an embodiment of the deodorizing material block forming apparatus according to the present invention;
5 is a side view showing an example of a heating unit constituting an embodiment of the deodorizing material block molding apparatus according to the present invention.

Hereinafter, an embodiment of the deodorizing material block molding apparatus according to the present invention will be described with reference to the accompanying drawings.

1 is a front view showing an embodiment of the deodorizing material block forming apparatus according to the present invention.

As shown in Figure 1, an embodiment of the deodorizing material block molding apparatus according to the present invention, the base frame 100, the lower mold unit 200, the powder supply unit 300, the cleaning unit 400, the upper It includes a mold unit 500 and a heating unit 600 .

As an example of the base frame 100, the base frame 100 includes a main body 110 having an accommodating space therein, and a cover frame 120 provided on the upper portion of the main body 110 to form an inner space. do.

The lower mold unit 200 is mounted on the upper surface of the base frame 100 . As an example of the lower mold unit 200 , as shown in FIGS. 2 and 3 , the lower mold unit 200 includes a base mold 210 fixed to the base frame 100 , and the edge of the base mold 210 . A plurality of guide pins 220 provided in the vertical direction, and the guide pins 220 are coupled to move up and down to be placed on the upper surface of the base mold 210 and the first mold 230 and the A first mold driving unit 240 for moving the first mold up and down, a second mold 250 coupled to the guide pins 220 to move up and down and placed on the upper surface of the first mold 230, 2 and a second mold driving unit 260 for moving the mold 250 up and down. The plurality of guide pins 220 is preferably four.

The base mold 210 includes a square plate-shaped base plate 211 having a uniform thickness, and hole forming pins 212 provided on an upper surface of the base plate to form a plurality of groups. Guide pins 220 are positioned at the four corners of the base plate 211 in the vertical direction, respectively. The plurality of hole-forming pin groups are preferably arranged in two rows, and each hole-forming pin group is positioned such that the hole-forming pins 212 form a plurality of rows inside the rectangular unit area, and the hole-forming pins 212 are arranged in a plurality of rows. It is preferable to have a round bar shape having a uniform outer diameter and length. The cross-sectional shape of the hole forming pin 212 may be a rectangle, a hexagon, or the like.

The first mold 230 includes a square plate-shaped base plate 231 having a uniform thickness, support blocks 232 coupled to correspond to the hole forming pin groups on the upper surface, and hole forming of the hole forming pin group. The pins 212 include pin insertion holes 233 formed to penetrate the support block 232 and the base plate 231 so as to penetrate the support block 232 . At the four corners of the base plate 231, guide holes 234 through which the guide pins 220 pass are provided, respectively. It is preferable that the number of support blocks 232 is equal to the number of hole forming groups, and the plane of the support blocks 232 is rectangular. In the first mold 230, guide pins 220 are inserted through each of the guide holes 234, and hole forming pins 212 are inserted through each of the pin insertion holes 233 of the support blocks 232, respectively. It is coupled, and it is possible to move up and down.

The first mold driving unit 240 moves the first mold 230 up and down. It is preferable to include a hydraulic cylinder as an example of the first mold driving unit 240 . The hydraulic cylinder is installed vertically and the end of the rod of the hydraulic cylinder is connected to a connecting plate extending and protruding from one side of the first mold 230, and the first mold 230 is moved up and down in a set height range by the operation of the hydraulic cylinder. moves with The first mold driving unit 240 may be implemented in various forms.

The second mold 250 includes a square plate-shaped base plate 251 having a uniform thickness, and forming holes 252 provided in the base plate 251 so that the support blocks 232 are respectively inserted therethrough. Guide holes 253 through which the guide pins 220 pass are provided at four corners of the base plate 251, respectively. The number of forming holes 252 is the same as the number of the support blocks 232 , the forming holes 252 are square and the same as the support block 232 , and the plane size of the forming holes 252 is the plane of the support block 232 . It is the same as the size, and the thickness of the support block 232 is the same as the thickness of the base plate 251 of the second mold 250 . The second mold 250 is coupled so that the guide pins 220 are inserted through the guide holes 253, respectively, and are inserted through the molding holes 252 of the support blocks 232, respectively, and can move up and down. .

The height of the hole forming pin 212 of the base mold 210 is equal to the sum of the thickness of the base plate 231 and the support block 232 of the first mold 230 and the thickness of the second mold 250 .

The second mold driving unit 260 moves the second mold 250 up and down. It is preferable to include a hydraulic cylinder as an example of the second mold driving unit 260 . The hydraulic cylinder is installed vertically, and the end of the rod of the hydraulic cylinder is connected to a connecting plate that extends and protrudes on one side of the second mold 250 to move the second mold 250 up and down in a set height range by the operation of the hydraulic cylinder. moves with The second mold driving unit 260 may be implemented in various forms.

When the second mold driving unit 260 moves the second mold 250 downward, the lower mold unit 200 is formed in the molding holes 252 of the second mold 250 of the first mold 230, respectively. The support blocks 232 are inserted, and at this time, the upper surface of the support block 232 and the upper surface of the second mold 250 form the same plane, and the hole forming pins 212 are exposed on the upper surface of the support block 232 . In this state, the hole forming pins 212 and the upper surfaces of the second mold 250 are cleaned by the cleaning unit 400 . When the second mold driving unit 260 moves the second mold 250 upward, a molding space is formed by the inner surface of the forming hole 252 of the second mold 250 and the upper surface of the support block 232 and the second The forming hole 252 of the mold 250 surrounds the hole forming pin group so that the hole forming pin group is located in the forming space. In this state, the powder supply unit 300 fills the molding spaces with powder. Each of the molding spaces is filled with powder, the powder filled in the molding space is pressurized by the upper mold unit 500 and heated by the heating unit 600 , and then the first mold driving unit 240 makes the first mold 230 . When moving upward, the support block 232 is inserted into the molding hole 252 of the second mold 250 to move the molded object molded in the molding space onto the upper surface of the second mold 250 .

The powder supply unit 300 is provided on one side of the base frame 100 and supplies the powder to be worked to the mold of the lower mold unit 200 while reciprocating toward the lower mold unit 200 . The powder to be worked includes activated carbon powder having a deodorizing function. As an example of the ingredient powder supply unit 300, the powder supply unit 300 includes a guide plate 310 positioned on the same plane as the upper surface of the mold of the lower mold unit 200, and a lower surface of the guide plate 310. A powder transport tube 320 placed in contact with the upper and lower openings, and a hopper unit 330 positioned on the upper portion of the powder transport tube 320 and supplying the powder to be worked to the powder transport tube 320 while moving up and down, and , a transfer tube driving unit that reciprocates the powder transfer tube 320 to the mold of the lower mold unit 200 and fills the mold (the molding space of the second mold) with the powder to be worked inside the powder transfer tube 320 ( 340). The upper surface of the guide plate 310 is flat, and the upper surface of the second mold 250 and the upper surface of the guide plate 310 are on the same plane in a state in which the second mold 250 of the lower mold unit 200 is moved upward. It is installed and fixed to the base frame 100 so as to be positioned on it. The powder transfer tube 320 is preferably formed in the shape of a square tube with open top and bottom. The lower surface of the powder transfer tube 320 is in contact with the upper surface of the guide plate 310 . The hopper unit 330 includes a powder storage bin 331 fitted to the upper end of the powder transport bin 320 so as to be movable up and down, and a storage bin driving unit 332 that moves the powder storage bin 331 up and down, and a powder storage bin ( It includes an opening/closing plate (not shown) for opening and closing the lower end of the 331 , and a hopper 333 connected to the powder storage container 331 by a corrugated pipe to receive the powder.

The powder supply unit 300 stores the powder to be worked in the powder storage bin 331 through the hopper 333, and opens and closes the lower end of the powder storage bin 331 with an opening and closing plate to transfer the powder of the powder storage bin 331 to the powder transfer bin It is transferred to (320). The powder storage bin 331 is moved upward with the storage bin driving unit 332 to separate the powder storage bin 331 from the powder transport 320. 200), the powder transfer barrel 320 moves to the upper surface of the lower mold unit 200 in a state in contact with the guide plate 310, while the molding spaces of the lower mold unit 200 are filled with powder and transferred. The barrel driving unit 340 moves the powder transport barrel 320 back to the original position. When the powder transport bin 320 is returned to its original position, the storage bin driving unit 332 moves the powder storage bin 331 downward to fit the lower end of the powder reservoir 331 to the upper end of the powder transport bin 320, and then opens and closes the opening and closing plate to transfer the powder in the powder storage container 331 to the powder transfer container 320 .

The cleaning unit 400 is provided on the other side of the base frame 100 and cleans the mold of the lower mold unit 200 while reciprocating toward the lower mold unit 200 . The cleaning unit 400 is preferably located on the opposite side of the powder supply unit 300 with respect to the lower mold unit 200 . As an example of the cleaning unit 400 , as shown in FIGS. 1 and 4 , the cleaning unit 400 includes a head frame 410 and a rotational driving unit mounted on the head frame 410 to generate rotational force. 420, a roll brush 430 that is rotatably coupled to the lower portion of the head frame 410 and cleans the powder remaining in the mold by rotation, and the rotational force of the rotation drive unit 420 is applied to the roll brush 430 The power transmission unit 440 that transmits to the power transmission unit 440, the powder suction unit 450 that is located on the rear side of the roll brush 430 and sucks the powder cleaned by the roll brush 430, and the head frame 410 are horizontally mounted. and a head frame driving unit 460 for reciprocating in the direction.

The powder suction unit 450 is located adjacent to the rear of the roll brush 430 and includes a suction head 451 through which powder is sucked, a flexible discharge pipe 452 connected to the suction head 451, and a discharge pipe 452. ) and a dust collector 453 connected to, and an air pumping unit (not shown) for generating a suction force. It is preferable that an auxiliary suction head 455 is further provided on the front side of the roll brush 430 . The auxiliary suction head 455 is connected to the dust collector 453 by the discharge pipe.

In the cleaning unit 400, the head frame driving unit 460 moves the head frame 410 to the lower mold unit 200 in a state in which the rotation driving unit 420 operates to rotate the roll brush 430 and the air pumping unit is operated. ), the roll brush 430 brushes the powder remaining in the mold of the lower mold unit 200, and the suction head 451 of the powder suction unit 450 sucks the powder blown off by the roll brush 430. The mold of the lower mold unit 200 is cleaned while being introduced into the dust collector 453 .

The upper mold unit 500 is located on the upper side of the lower mold unit 200, and press-molded the powder filled in the mold of the lower mold unit 200 while moving up and down. As an example of the upper mold unit 500 , the upper mold unit 500 includes a fixed support member 510 that is fixedly installed above the lower mold unit 200 , and the fixed support member 510 is penetrated and coupled in a vertical direction. The hydraulic cylinder 520 and the mold base plate 530 that is coupled to the rod end of the hydraulic cylinder 520 and moves up and down according to the operation of the hydraulic cylinder 520, and the mold base plate 530 on the lower surface of the It includes a mold block 540 that is coupled and molded with the mold of the lower mold unit 200 . It is preferable that a plurality of guide shafts 550 are coupled to the upper surface of the mold base plate 530 , respectively, and the guide shafts 550 are penetrated through the fixed support member 510 to guide the movement of the mold base plate 530 , respectively. Do. The fixed support member 510 is preferably formed in the shape of a square plate and positioned in the horizontal direction, and the fixed support member 510 includes a plurality of support shafts coupled to the body 110 of the base frame 100 in a vertical direction. It is preferably coupled to the end. The mold base plate 530 has a rectangular plate shape, and is preferably formed in a size corresponding to the size of the second mold 250 of the lower mold unit 200 . The mold block 540 is provided in plurality, and the mold block 540 is provided with a plurality of pin insertion holes therein. The mold block 540 is provided on the lower surface of the mold base plate 530 so as to correspond to the molding holes 252 of the second mold 250 of the lower mold unit 200, and the mold block 540 is the lower mold unit. (200) is formed in the same size and shape as the support block 232 of the first mold 230.

In the upper mold unit 500 , the hydraulic cylinder 520 is operated to move the mold base plate 530 downward, and the mold blocks 540 coupled to the lower surface of the mold base plate 530 are removed from the lower mold unit 200 . The powders respectively filled in the forming holes 252 of the second mold 250 are press-molded by inserting them into the forming holes 252 of the second mold 250 . And the hydraulic cylinder 520 moves the mold base plate 530 upward to return it to its original position.

The heating unit 600 heats the powder compact of the lower mold unit 200 pressed by the upper mold unit 500 while reciprocating toward the lower mold unit 200 . The heating unit 600 is positioned between the powder supply unit 300 and the cleaning unit 400 and moves in the front-rear direction (refer to FIG. 1 ). As an example of the heating unit 600, as shown in FIG. 5, the heating unit 600 includes a straight guide unit 610 provided in the base frame 100, and a mounting coupled to the straight guide unit 610. A member 620, a mounting member driving unit 630 for reciprocally driving the mounting member 620 in a horizontal direction, a hydraulic cylinder 640 penetratingly coupled to the mounting member 620 in a vertical direction, and the hydraulic cylinder It is coupled to the rod end of the 640 and includes a heater base member 650 that moves up and down according to the operation of the hydraulic cylinder 640 , and a heater 660 coupled to the heater base member 650 . It is preferable that a plurality of guide shafts 670 are coupled to the upper surface of the heater base member 650 , respectively, and the guide shafts 670 penetrate through the mounting member 620 to guide the movement of the heater base member 650 . The straight guide unit 610 is installed on the base frame 100 so that the mounting member 620 moves horizontally in the front-rear direction. As an example of the straight guide unit 610, the straight guide unit 610 includes two guide bars 611 spaced apart from each other, and a sliding block 612 that is slidably coupled to the guide bar 611. include The mounting member 620 is coupled to the two sliding blocks 612 . The mounting member driving unit 630 may include a hydraulic cylinder or a ball screw assembly and a rotation motor.

The heating unit 600 is mounted by moving the mounting member 620 in the horizontal direction along the straight guide unit 610 when the mounting member driving unit 630 operates to push the mounting member 620 toward the lower mold unit 200 . The heater base member 650 mounted on the member 620 is positioned above the lower mold unit 200 . The hydraulic cylinder 640 mounted on the mounting member 620 moves the heater base member 650 downward, and the heat generated from the heater 660 of the heater base member 650 fills the mold of the lower mold unit 200 with the powder. The molded body is heated. And after the hydraulic cylinder 640 moves the heater base member 650 upward, the mounting member driving unit 630 moves the mounting member 620 to its original position.

Hereinafter, the operation of the deodorizing material block molding apparatus according to the present invention will be described.

First, the cleaning unit 400 primarily cleans the mold of the lower mold unit 200 while reciprocating to the lower mold unit 200 . When the lower mold unit 200 includes the base mold 210 and the first and second molds 230 and 250, the second mold 250 is moved downward so that the groove forming pins 212 are formed in the second mold. The upper surface of the second mold 250 is cleaned in a state exposed above 250 . Then, the powder supply unit 300 reciprocates toward the lower mold unit 200 in a state in which the second mold 250 moves upward to form forming spaces in the second mold 250 and transfers the powder to be worked into the lower mold unit. Each of the mold forming spaces of 200 is filled with powder. The upper mold unit 500 moves downward to pressurize the powder each filled in the mold forming spaces of the lower mold unit 200 for a set time and move upward. Then, the cleaning unit 400 reciprocates to the lower mold unit 200 to secondly clean the powder scattered in the mold of the lower mold unit 200 . The heating unit 600 moves in the horizontal direction and moves downward in a state positioned on the mold of the lower mold unit 200 to heat the molded bodies respectively molded in the mold forming spaces of the lower mold unit 200 for a set time. And the heating unit 600 moves to the original position. Then, the first mold 230 of the lower mold unit 200 is moved upward to move the deodorizing material blocks, which are molded bodies heated and pressed in the second mold 250, out of the molding space. The deodorant blocks are discharged through a discharge guide plate (not shown) provided on the front side of the lower mold unit 200 . While repeating the above operation, the deodorizing material blocks are continuously manufactured.

100; base frame 200; lower mold unit
300; powder supply unit 400; cleaning unit
500; upper mold unit 600; heating unit

Claims (5)

base frame;
a lower mold unit mounted on the upper surface of the base frame;
a powder supply unit provided on one side of the base frame and reciprocating toward the lower mold unit to supply a powder to be worked on to the mold of the lower mold unit;
a cleaning unit provided on the other side of the base frame to clean the mold of the lower mold unit while reciprocating toward the lower mold unit;
an upper mold unit located above the lower mold unit and configured to pressurize the powder filled in the mold of the lower mold unit while moving up and down; and
and a heating unit positioned between the powder supply unit and the cleaning unit and configured to heat the powder compact of the lower mold unit pressurized by the upper mold unit while reciprocating toward the lower mold unit. According to claim 1, wherein the lower mold unit is coupled to a base mold fixed to the base frame, a plurality of guide pins provided in a vertical direction to the edge of the base mold, and the guide pins to move up and down to the A first mold placed on the upper surface of the base mold, a first mold driving unit that moves the first mold up and down, and a second mold that is vertically movably coupled to the guide pins and placed on the upper surface of the first mold; , comprising a second mold driving unit for moving the second mold up and down,
The base mold includes a base plate and hole forming pins provided to form a plurality of groups on the upper surface of the base plate,
The first mold includes a base plate, support blocks coupled to correspond to the hole-forming pin groups on the upper surface, and the support block and the base plate so that the hole-forming pins of the hole-forming pin group penetrate the support block. It includes pin insertion holes formed to pass through,
The second mold is a base plate and a deodorizing material block forming apparatus including forming holes provided in the base plate so that the support blocks are respectively inserted therethrough. According to claim 1, wherein the powder supply unit is installed on the base frame and a guide plate positioned on the same plane as the upper surface of the mold of the lower mold unit, the lower surface of the guide plate is placed so that the contact with the upper and lower powder A transfer tube, a hopper unit located on the upper part of the powder transfer tube and moving up and down to supply the powder to be worked to the powder transfer tube, and a work object inside the powder transfer tube while reciprocating the powder transfer tube to the mold of the lower mold unit A deodorizing material block molding device including a barrel driving unit for filling the mold with powder. According to claim 1, wherein the upper mold unit is coupled to a fixed support member fixedly installed above the lower mold unit, a hydraulic cylinder that is vertically coupled to the fixed support member, and a rod end of the hydraulic cylinder. A deodorizing material block forming apparatus comprising: a mold base plate moving up and down according to the operation of a hydraulic cylinder; and a mold block coupled to a lower surface of the mold base plate and molded with the mold of the lower mold unit. According to claim 1, wherein the heating unit comprises a linear guide unit provided on the base frame, a mounting member coupled to the linear guide unit, a mounting member driving unit for reciprocally driving the mounting member in a horizontal direction; A deodorizing material block molding comprising a hydraulic cylinder penetratingly coupled to the member, a heater base member coupled to the rod end of the hydraulic cylinder and moving up and down according to the operation of the hydraulic cylinder, and a heater coupled to the heater base member Device.

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