KR20120107690A - Apparatus for manufacturing brick and movable equipment for manufacturing brick containing the same - Google Patents

Abstract

PURPOSE: A brick manufacturing apparatus including a material input unit and a pressurization unit and mobile brick manufacturing facility including the same are provided to manufacture bricks which have the equalized thickness. CONSTITUTION: A rotatory body(130) is rotatably installed on a support plate(120). The rotatory body includes a molding frame. A first pressurization unit(160) compresses raw materials inputted using a raw material input unit(150). Another raw material input unit(170) additionally inputs raw materials for controlling thickness to the compressed molded material. A second pressurization unit(180) compresses the raw materials inputted using the another raw material unit. A push unit(190) pushes the molded material.

Description

Brick manufacturing apparatus and mobile brick manufacturing equipment including the same {APPARATUS FOR MANUFACTURING BRICK AND MOVABLE EQUIPMENT FOR MANUFACTURING BRICK CONTAINING THE SAME}

The present invention relates to a brick manufacturing apparatus and a mobile brick manufacturing apparatus including the same, and more particularly, to a brick manufacturing apparatus capable of manufacturing a brick having a high compressive strength and a uniform thickness, and a mobile brick manufacturing apparatus including the same. The present invention relates to a mobile brick manufacturing facility capable of manufacturing bricks at a construction site, thereby reducing logistics distribution costs.

In general, a brick of a predetermined size is used to construct a wall of a building or to finish a floor of a ground. As a raw material of the brick, various materials such as concrete, cement, loess, clay and kaolin are used, and recently, loess is preferred. Bricks are classified into dry and wet bricks according to the moisture content of the raw materials used in the manufacturing process. In addition, brick is divided into extrusion type and press type according to the shaping | molding method.

The extrusion type is extruded by inserting the wet raw material into the extruder, and then proceeds to a method of cutting to a predetermined size, which has the advantage of high productivity. However, the extrusion type has a disadvantage of low strength (compressive strength, etc.) of the brick.

In the press type, a raw material is put into a molding die having a certain shape and size, and then pressurized (press) through a hydraulic press. Compared to the extruded type, the press type is capable of using wet raw materials as well as dry raw materials, and has an advantage of manufacturing bricks having high strength (compressive strength, etc.). However, the press type is less productive than the extruded type. In connection with such a press type, a manufacturing apparatus capable of increasing productivity by continuously manufacturing in recent years has been proposed. This is shown in Figures 1 and 2 attached.

1 and 2, the brick manufacturing apparatus includes a hopper 10 for supplying raw materials, a disk-shaped rotating body 4 provided with a forming mold 20, and raw materials filled in the forming mold 20. Two push plates 30 and 31 pressed upward and downward in the molding die 20, and a push plate 40 pushing and removing the completed bricks by pressing the press plates 30 and 31. ) And a belt conveyor 50 for transporting the stripped bricks.

At this time, the disk-shaped rotating body 4 is provided with four forming molds 20 to rotate by 90 degrees. Therefore, according to the manufacturing apparatus shown in Figures 1 and 2, the raw material is filled in the mold 20 from the hopper 10, the pressure is pressed (compressed) by the two upper and lower pressure plates 30, 31 to form a brick. . Thereafter, the molded brick is positioned below the push plate 40 by the 90 degree rotation of the disk-shaped rotating body 4, and is removed to the belt conveyor 50 by the driving of the push plate 40.

The brick manufacturing apparatus shown in FIG. 1 and FIG. 2 has a high compressive strength and is capable of producing continuous bricks to increase productivity. However, the conventional brick manufacturing apparatus including the manufacturing apparatus shown in Figs. 1 and 2 is difficult to manufacture a brick having a uniform thickness. Specifically, the moisture (moisture content), particle size distribution, density, etc. are different for each raw material introduced into the mold 20, even if the same pressure is applied to the mold 20 through the pressure plate 30, 31, the thickness of each brick The difference occurs. That is, the conventional press-type manufacturing apparatus, but can manufacture a brick having a high compressive strength and the like, there is a problem that the thickness difference occurs for each brick can not take a separate technical means for uniform thickness.

In addition, the brick manufacturing apparatus shown in FIG. 1 and FIG. 2 is a structure that presses the raw material injected into the mold 20 in the vertical direction, the problem is also complicated device. Specifically, the upper and lower two pressure plates 30, 31, as well as the two hydraulic cylinders 32, 33 for driving the two pressure plates 30, 31 are arranged up and down, the device is complicated. .

On the other hand, conventional bricks are generally manufactured at a production plant, and then transported to a construction site. Accordingly, there is a problem that the logistics cost such as transportation costs such as transport costs for transferring the raw materials to the manufacturing plant as well as transport costs for transferring the manufactured bricks from the factory to the construction site is increased, thereby increasing the unit price of the bricks.

The present invention is to solve the problems of the prior art as described above, it is an object of the present invention to provide a brick manufacturing apparatus capable of manufacturing a brick having a high thickness, as well as a uniform thickness.

In addition, an object of the present invention is to provide a mobile brick manufacturing equipment that can directly manufacture a brick at a construction site, such as to reduce the logistics distribution cost (transportation cost, etc.).

The present invention to achieve the above object,

Support frame;

A support plate fixed to the support frame and having a discharge hole through which molded bricks are discharged;

A rotating body rotatably installed on the support plate and including a molding frame;

A first raw material input part which inputs a raw material to the mold;

A first pressurizing unit compressing the raw material introduced through the first raw material input unit;

A second raw material input part which further inputs a raw material for thickness control on the molded product compressed by the first pressing part;

A second pressurizing unit which presses the raw material introduced through the second raw material input unit; And

And a push unit for pushing the molded product so that the molded product compressed by the second pressing unit is discharged through the discharge hole of the support plate.

The forming mold has an upper portion and a lower portion open, and when the first pressing portion and the second pressing portion are pressed, the lower portion of the forming mold provides a brick manufacturing apparatus for supporting the molded product by being in close contact with the support plate.

According to a preferred embodiment of the present invention, the rotating body includes an upper table, a lower table positioned below the upper table, and the forming mold includes an upper frame positioned between the upper table and the lower table, and the upper frame. It is preferable to include a lower frame extending from, and formed below the lower table. In this case, it is preferable that a gear portion is coupled to the bottom of the lower table, and the support plate is provided with a support shaft axially coupled to the inner circumferential surface of the gear portion and a motor for engaging the outer circumferential surface of the gear portion to rotate the gear portion.

In addition, the brick manufacturing apparatus according to the present invention further comprises an upper frame installed on the upper portion of the support frame, the first pressing unit and the second pressing unit is preferably fixed to the upper frame. In addition, the brick manufacturing apparatus according to the present invention comprises a raw material sorter; And it may further comprise a raw material conveying conveyor for supplying the raw material selected through the raw material sorting unit to the first raw material input unit and the second raw material input unit.

In addition, the present invention,

transportation; And

It provides a mobile brick manufacturing equipment comprising a brick manufacturing apparatus mounted on the vehicle. At this time, the brick manufacturing apparatus mounted on the vehicle is composed of a brick manufacturing apparatus according to the present invention as described above.

According to the brick manufacturing apparatus of the present invention, as a means for controlling the thickness, the compressive strength is high, including a second raw material input portion and the second pressing portion for inputting and compressing the second raw material on the primary molded molding Of course, it has the effect of producing a brick having a uniform thickness. In addition, according to the present invention, the brick can be continuously manufactured to increase the productivity, and the raw material is pressed and pressed over two times, thereby making it possible to manufacture a brick having an improved compressive strength.

In addition, according to the mobile brick manufacturing equipment of the present invention, the bricks can be manufactured by moving the manufacturing equipment itself to the raw material supply site or the construction site without transferring the raw materials to the manufacturing plant or transferring the manufactured brick from the factory to the construction site. . Accordingly, it is possible to reduce the logistics distribution cost (transportation cost, storage cost, etc.) has the effect of lowering the unit price of the brick.

1 is a perspective view showing a brick manufacturing apparatus according to the prior art.
Figure 2 is a cross-sectional configuration view showing a brick manufacturing apparatus according to the prior art, it is a cross-sectional configuration of the brick manufacturing apparatus shown in FIG.
3 is a perspective view of a brick manufacturing apparatus according to the present invention.
Figure 4 is a perspective view of the main part of the brick manufacturing apparatus according to the present invention.
5 is an exploded perspective view of main parts of a brick manufacturing apparatus according to the present invention.
6 is a sectional view of the brick manufacturing apparatus according to the present invention and an enlarged sectional view of main parts.
7 is a side view of a mobile brick manufacturing equipment according to the present invention.
8 is a plan view of a mobile brick manufacturing equipment according to the present invention.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. The accompanying drawings show exemplary embodiments of the present invention, which are provided only to assist in understanding the present invention, and thus the technical scope of the present invention is not limited thereto.

3 is a perspective view of a brick manufacturing apparatus according to the present invention, Figure 4 is a perspective view of the main part of the brick manufacturing apparatus according to the present invention. In addition, Figure 5 is an exploded perspective view of the main portion of the brick manufacturing apparatus according to the present invention, Figure 6 is a cross-sectional view and enlarged sectional view of the brick manufacturing apparatus according to the present invention. In addition, Figures 7 and 8 are shown as an exemplary mobile brick manufacturing equipment according to the present invention, Figure 7 is a side view of the mobile brick manufacturing equipment according to the present invention, Figure 8 is a mobile brick manufacturing equipment according to the present invention. Top view from above.

First, referring to Figures 3 to 6, the brick manufacturing apparatus according to the present invention is the support frame 110, the support plate 120, the rotating body 130, the forming frame 140, the first raw material input portion 150, a first pressing unit 160, a second raw material input unit 170, a second pressing unit 180, and a push unit 190.

The support frame 110 supports the components constituting the apparatus 100 according to the present invention, which may be installed in the apparatus 100 as illustrated in the drawing. For example, as shown in the figure, the support frame 110 is fixedly installed on the floor frame 112 seated on the ground, vertically installed on both sides (left and right) of the floor frame 112. Can be.

The support plate 120 is fixedly installed on the support frame 110. Support plate 120 may be fixed, installed in the middle of the support frame 110, as illustrated in the figure. The support plate 120 preferably has a disc shape. In addition, the support plate 120 is formed with a discharge port 125 (see Fig. 5) for discharging the brick formed in the molding die 140 to the bottom. One or two discharge ports 125 may be formed on the support plate 120. 5 illustrates a state in which one discharge port 125 is formed.

The rotating body 130 is installed to be rotatable on the support plate 120. The rotating body 130 may be rotated by, for example, driving of the motor (M). The rotating body 130 is preferably rotated by 60 degrees. According to a preferred embodiment, the rotating body 130 may include an upper table 132 and a lower table 134 located below the upper table 132 as illustrated in the drawing. The upper table 132 and the lower table 134 preferably have a disc shape. In this case, a support 133 may be installed between the upper table 132 and the lower table 134. Accordingly, the upper table 132 and the lower table 134 may be spaced apart at predetermined intervals while being integrally rotated by a support 133 installed therebetween.

In addition, the rotating body 130 includes a plurality of molding die 140. Rotating body 130, it is preferable to include six forming molds 140 are arranged at equal intervals as shown in the drawing (see Fig. 5). The molding die 140 may have various shapes. The molding die 140 may be determined according to a shape of a product (brick) to be formed, and an internal shape thereof. Molding mold 140 may have a rectangular parallelepiped shape, for example, as shown in the figure.

In addition, the upper and lower portions of the forming die 140 are open (opened). At this time, the molding die 140 is according to a preferred embodiment, as shown in the figure, the upper frame 142 located between the upper table 132 and the lower table 134, and from the upper frame 142 It is preferable that the lower frame 144 is integrally extended and formed and positioned below the lower table 134. When the raw material is introduced into the mold 140 and the raw material is pressed, the support plate 120 adheres to the lower part of the mold 140 to support the raw material. More specifically, the support plate 120 is in close contact with the bottom of the lower frame 144 in the process of the raw material is added or compressed. That is, the support plate 120 acts as a base plate to seal the lower portion of the molding die 140 in the raw material input process and the pressing process.

The first raw material input part 150 is a first input of the raw material to the molding die 140, which is located on the top of the rotating body (130). More specifically, the end (discharge portion) of the first raw material input portion 150 is located at the upper portion of the forming mold 140. At this time, the end (discharge portion) of the first raw material input portion 150 may have the same shape as the molding die 140 as shown in the figure. The first raw material input part 150 may have a structure as usual, and a predetermined amount of raw material is input to the molding die 140.

The first pressing unit 160 is a first compression (press) of the raw material introduced through the first raw material input unit 150, which may be configured as usual. For example, the first pressing unit 160 is configured to include a pressure plate 162 for pressing the input material as shown in the figure, and a hydraulic cylinder 164 to move the pressure plate 162 up and down. Can be.

The second raw material input unit 170 is a further input of the raw material (secondary raw material input) on the molded article compressed by the first pressing unit 160, which is the same as the first raw material input unit 150 Can be configured. At this time, the raw material introduced through the second raw material input unit 170 is for adjusting the thickness, the second raw material input unit 170 is a small amount of raw material is added to the first raw material input unit 150. That is, most of the raw material constituting the brick is input in the first raw material input unit 150, and the raw material for thickness control is input in the second raw material input unit 170. In addition, as shown in FIG. 3, the upper portion of the second raw material input portion 170 may have a structure in communication with the upper portion of the first raw material input portion 150.

The second pressing unit 180 is a second pressing (press) of the raw material introduced through the second raw material input unit 170, which may have the same structure as the first pressing unit 160. For example, the second pressing unit 180 is configured to include a pressure plate 182 for pressing the input material as shown in the figure, and a hydraulic cylinder 184 to move the pressure plate 182 up and down. Can be.

The push unit 190 is to push and eject the molded article pressed by the second pressing unit 180, which may be configured as usual. For example, the push unit 190 is a push plate 192 for pushing the molded (brick) pressed and molded in the molding die 140, as shown in the figure, and the push plate 162 It may be configured to include a hydraulic cylinder 194 to move up and down. At this time, the molded article (brick) pressed and molded in the molding die 140 is discharged through the discharge port 125 of the support plate 120 by the push action of the push unit 190.

3 and 6, the brick manufacturing apparatus according to the present invention may further include an upper frame 115 installed on the support frame 110. The upper frame 115 may include a bottom plate 115a and two side plates 115b formed vertically from the bottom plate 115. In this case, as shown in the figure, the first pressing unit 160 and the second pressing unit 180 may be fixed and installed on the upper frame 115. More specifically, the first pressing unit 160 and the second pressing unit 180 is fixed and installed on the bottom plate 115a of the upper frame 115, the pressing plate 162, 182 is the bottom plate 115a. Located at the bottom of the), the hydraulic cylinders 164 and 184 may be located at the top of the bottom plate (115a). In addition, the push part 190 may be fixed and installed on the side plate 115b of the upper frame 115, and may be fixed and installed through the side plate 115b and the bracket 116.

In addition, the brick manufacturing apparatus 100 according to the present invention may further include a discharge conveyor 118 installed in the lower portion of the support plate 120. The discharge conveyor 118 transfers the molding (brick) discharged from the discharge port 125 of the support plate 120 to the outside, which may be configured as usual.

In addition, as described above, the rotating body 130 is installed to be rotatable on the support plate 120, it may be configured to include an upper table 132 and a lower table 134, this time Figure 5 6, a ring-shaped gear part 138 is coupled to a bottom surface of the lower table 134, and an inner circumferential surface of the gear part 138 is connected to an upper portion of the support plate 120. The shaft coupled support shaft 128 may have a structure in which it is installed. In this case, the lower table 134 and the gear unit 138 may be coupled through welding or a fixture 139. In addition, the support shaft 128 may be integrally installed on the upper portion of the support plate 120 or may be installed through welding or fixture 129. In addition, the support plate 120 may be fixed and installed by a motor (M) for engaging the outer circumferential surface of the gear unit 138 to rotate the gear unit 138. That is, the gear unit 138 is a gear (138a, gear) is formed on the outer circumferential surface of the gear body, which is geared with the gear (Ma) formed on the shaft of the motor (M) is rotated. More specifically, the support shaft 128 is axially coupled to the inner circumferential surface of the gear unit 138, and the motor M is gearably coupled to the outer circumferential surface of the gear unit 138. Therefore, when the motor M rotates, the gear part 138 rotates about the support shaft 128, and the rotating body 130 rotates by this. The motor M may be a hydraulic motor or the like. In this case, the motor M may be controlled by a controller (not shown) so that the rotor 130 may be rotated by a predetermined angle, that is, by 60 degrees.

Referring to the process of manufacturing a brick using the brick manufacturing apparatus 100 according to the present invention as follows.

First, a predetermined amount of raw material is firstly supplied into the molding die 140 through the first raw material input part 150. The raw material used in the present invention is not limited as long as it can be used as a raw material of the brick, for example, the raw material may be selected from various materials such as concrete, cement, loess, clay and kaolin. The raw material may be one or two or more mixtures selected from those listed above. The raw material preferably contains at least ocher. In addition, the raw material may be a dry powder having a low moisture content, or a kneaded product in which moisture is artificially added to the dry powder. In addition, the raw material may include a fiber, straw or the like as a reinforcing material for strength reinforcement, and may further include a fixing agent for fixing or a color material for realizing color.

When the raw material is first injected into the molding die 140 as described above, the rotating body 130 is rotated by 60 degrees so that the molding die 140 into which the raw material is injected is located under the first pressing unit 160. And the primary molded object of a predetermined shape is shape | molded by the crimping | compression-bonding of the 1st press part 160 (primary pressurization). Thereafter, the first molded product is positioned below the second raw material input part 170 by the rotation of the rotor 130. And the raw material for thickness control is further charged (secondary raw material input) from the second raw material input unit 170 on the primary molded product. Next, the rotating body 130 is rotated by 60 degrees so that the molding die 140 into which the second raw material is injected is positioned of the second pressing unit 180. And the final molding (brick) is shape | molded by the crimping | compression-bonding (secondary pressurization) of the 2nd press part 180. FIG.

Thereafter, the rotating body 130 is rotated by 60 degrees such that the final molding (brick) is positioned on the discharge hole 125 formed in the support plate 120, that is, the lower part of the push part 190. And by the push action of the push part 190, the final molded object (brick) is removed from the shaping | molding die 140, and is discharged through the discharge port 125. FIG. At this time, the molded product (brick) discharged through the discharge port 125 is discharged onto the discharge conveyor 118 installed under the support plate 120 is transported to the outside.

In addition, as described above, the molding die 140 is open (opening) the upper and lower, the support plate 120 in the lower portion of the molding die 140 in the input process and the pressing process of the raw material into the molding die 140 ) Closely adheres to support the raw materials. That is, in the input process and the pressing process of the raw material, the support plate 120 acts as a base plate of the molding die 140.

According to the brick manufacturing apparatus 100 of the present invention described above, it is possible to manufacture a brick having a high strength such as compressive strength as a press type. In addition, as the rotating body 130 is rotated, that is, a plurality of molds 140 are rotated, raw materials may be continuously input, compressed, and discharged to increase productivity of bricks.

In particular, according to the brick manufacturing apparatus of the present invention, it is possible to continuously manufacture a brick having a uniform thickness, including the thickness adjusting means. Specifically, after the high compressive strength brick (primary molding) is manufactured through the first raw material input unit 150 and the first pressing unit 160, the second secondary on the primary molding as a thickness control means Including the second raw material input unit 170 and the second pressing unit 180 to input and compress the raw material, it is possible to continuously manufacture a brick having a uniform thickness. That is, bricks which are almost the same as the volume (height) of the forming mold 140 are molded by the secondary raw material input and compression, and the thickness difference for each brick produced is small, and the compressive strength is obtained by the second compression. Is improved.

Moreover, as a pressurizing structure which pressurizes a raw material, conventionally pressurizes a raw material in both upper and lower directions as shown to FIG. 1 and FIG. 2, The manufacturing apparatus which concerns on this invention is a structure which presses only in an upper direction, Simple pressing structure and easy thickness control. That is, in the brick manufacturing apparatus according to the present invention, the raw material is supported by the adhesion of the support plate 120 at the lower portion of the molding die 140 when the raw material is inserted and pressed, and the first pressing only the upper portion of the molding die 140. The pressing unit 160 and the second pressurizing unit 180 are formed through the pressurizing structure, so that the pressurizing structure is simple. In addition, the main thickness of the brick is determined by the pressing force of the first pressing unit 160, and then controlled by the second raw material input unit 170 and the second pressing unit 180 to produce a brick having a uniform thickness. Is possible.

7 and 8, the brick manufacturing apparatus 100 according to the present invention may further include a raw material sorting machine 70 and a raw material conveying conveyor 80. At this time, the raw materials collected at the raw material collection site is sorted into raw materials having a uniform size through the raw material sorting machine 70, and then the first raw material input unit 150 and the second raw material input unit (through the transfer conveyor 80) ( 170, and is supplied.

The raw material sorter 70 may be used as usual. The raw material sorter 70 is, for example, a raw material input hopper unit 72; A raw material sorting unit 74 having a screen net or the like installed as sorting the input raw materials by size; It may include; the discharge unit 76 for discharging the raw material (lump) having a large particle in the raw material selected by the sorting unit 74. In addition, the raw material sorter 70 may further include a crushing unit (not shown) and the like installed on the tip of the sorting unit 74. In addition, the additive sorting unit 70 may be further provided with an additive input unit 78 that can further mix the additive to the selected raw material before being discharged to the transfer conveyor 80. In this case, the additives may include, for example, reinforcing agents such as fibers or straws, fixing agents and color materials, but are not limited thereto.

On the other hand, referring to Figures 7 and 8, the movable brick manufacturing equipment according to the present invention is a transport means 200; And it includes a brick manufacturing apparatus 100 mounted on the vehicle 200. At this time, the brick manufacturing apparatus 100 is composed of a brick manufacturing apparatus 100 according to the present invention as described above. In the mobile brick manufacturing equipment according to the present invention, since the brick manufacturing apparatus 100 mounted on the transportation means 200 is composed of a brick manufacturing apparatus 100 according to the present invention as described above, a detailed description thereof Omit.

The vehicle 200 is included in the present invention as long as it can move (transport) by mounting the brick manufacturing apparatus 100, for example, the vehicle 200 from the vehicle or the like as shown in FIG. It may include a selected transport medium 210, and a mounting portion connected to the transport medium 210 to mount the brick manufacturing apparatus 100. The mount may, for example, use a trailer 220 as shown in the figure. In addition, in general, the large trailer 220 is provided with a hydraulic power pack 230, at this time, the hydraulic cylinder 164, the second pressing unit of the first pressing unit 160 constituting the brick manufacturing apparatus 100. Hydraulic pressure used for the hydraulic cylinder 184 of 180, the hydraulic cylinder 194 of the push unit 190, and the hydraulic motor M may be supplied from the hydraulic power pack 230 installed in the trailer 220. .

Therefore, the brick manufacturing equipment according to the present invention can be moved by the vehicle (200). The brick manufacturing equipment according to the present invention is moved to a building construction site (wall construction site of a building), for example, and can manufacture and supply a brick directly at the construction site. Specifically, the raw material is sorted through the sorting machine 70 at the construction site, and then the selected raw material is transferred and supplied to the first raw material input part 150 and the second raw material input part 170 through the transfer conveyor 80. By pressing, molding through the molding die 140 can be supplied brick. At this time, the molded brick, that is, the brick discharged to the outside of the device 100 through the belt conveyor 118 can be used for building the building walls by drying (natural drying or hot air drying) in a conventional manner.

In addition, the brick manufacturing equipment according to the present invention may be transferred to the raw material extraction site as well as the building construction site as described above to manufacture the brick. Specifically, the vehicle 200 may be transported to a raw material collecting site (for example, where many raw materials such as ocher are distributed) by the transportation means 200 to manufacture bricks at the raw material collecting site.

In addition, the brick manufacturing equipment according to the present invention may further include a firing furnace, so that the molded product (brick) discharged from the apparatus 100 may be used in a building after firing through the firing furnace. In addition, as shown in Figure 7, the brick manufacturing equipment according to the present invention may further include a cover 240 to cover and protect the device 100 during movement. In this case, the cover 240 may be configured in a box shape selected from a metal material or a plastic material, or may be configured as a flexible tent, but is not limited thereto. In FIG. 7 and FIG. 8, reference numeral 250 denotes an electric control box.

As described above, the brick manufacturing equipment according to the present invention is movable. Accordingly, according to the present invention, a brick may be manufactured by moving the brick manufacturing equipment itself to a raw material supply site (a place where raw materials are collected) without transferring the raw materials to a brick manufacturing plant. In addition, the brick manufacturing equipment can be moved to a construction site that requires bricks, for example, a building brick construction site, a floor sidewalk block construction site of the ground, and the like, so that bricks can be manufactured and used directly at the construction site.

Therefore, according to the present invention, it is possible to reduce the logistics distribution costs, such as transportation costs and storage costs generated by transferring the raw material of the brick from the raw material supply to the manufacturing plant, or from the manufacturing plant to the construction site as in the prior art Supply costs can be lowered.

100: brick manufacturing apparatus 110: support frame
120: support plate 130: rotating body
140: forming mold 150: first raw material input portion
160: first pressurizing unit 170: second raw material input unit
180: second pressing section 190: push section

Claims (7)

A support frame;
A support plate fixed to the support frame and having a discharge hole through which molded bricks are discharged;
A rotating body rotatably installed on the support plate and including a molding frame;
A first raw material input part which inputs a raw material to the mold;
A first pressurizing unit compressing the raw material introduced through the first raw material input unit;
A second raw material input part which further inputs a raw material for thickness control on the molded product compressed by the first pressing part;
A second pressurizing unit which presses the raw material introduced through the second raw material input unit; And
And a push unit for pushing the molded product so that the molded product compressed by the second pressing unit is discharged through the discharge hole of the support plate.
The forming mold has an upper and a lower opening, and when pressed by the first pressing portion and the second pressing portion, the lower portion of the forming mold is the brick manufacturing apparatus, characterized in that the support plate is in close contact with the molding support .
The method of claim 1,
The rotating body includes an upper table and a lower table positioned below the upper table,
The forming mold is a brick manufacturing apparatus comprising an upper frame positioned between the upper table and the lower table, and a lower frame extending and formed from the upper frame and positioned below the lower table.
The method of claim 2,
Gear parts are coupled to the bottom of the lower table,
The support plate is a brick manufacturing apparatus, characterized in that the support shaft is coupled to the inner peripheral surface of the gear portion and the motor to rotate the gear portion in engagement with the outer peripheral surface of the gear portion.
The method of claim 1,
The brick manufacturing apparatus further includes an upper frame installed on the upper portion of the support frame,
The first pressing unit and the second pressing unit brick manufacturing apparatus, characterized in that fixed to the upper frame.
The method of claim 1,
The rotating body is a brick manufacturing apparatus, characterized in that it comprises six molding frames.
The method of claim 1,
The brick manufacturing apparatus,
Raw material sorter; And
And a raw material conveying conveyor for supplying the raw material selected through the raw material sorting unit to the first raw material input part and the second raw material input part.
transportation; And
Including; brick manufacturing apparatus mounted on the vehicle;
The brick manufacturing apparatus is a mobile brick manufacturing equipment, characterized in that the brick manufacturing apparatus according to any one of claims 1 to 6.

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