A fully automatic brick unloading and packaging device for internally combusted bricks
By designing a fully automatic brick unloading and packaging device for internally combusted sintered bricks, the problem of repeated adjustments to the brick clamp during transportation was solved by utilizing the cooperation of the moving part and the clamping part. This enabled the rapid grabbing and movement of sintered bricks, improving the continuity and efficiency of packaging.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGMEN YUEZHILU ENVIRONMENTAL PROTECTION BUILDING MATERIALS CO LTD
- Filing Date
- 2025-06-30
- Publication Date
- 2026-06-30
AI Technical Summary
In the current process of packaging internally combusted bricks, the brick clamps need to be repeatedly adjusted during handling, which affects continuity and work efficiency.
Design a fully automatic brick unloading and packaging device for internal combustion sintered bricks. Through the cooperation of the moving part, clamping part and limiting component, the device can quickly grab and move the sintered bricks, ensuring the continuity of packaging.
It improves the continuity and efficiency of sintered brick packaging, reduces the number of times the brick clamps need to be adjusted, and enhances the overall automation level of the operation.
Smart Images

Figure CN224428049U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of sintered brick packaging technology, and in particular relates to a fully automatic brick unloading and packaging device for internally sintered bricks. Background Technology
[0002] Internally combustible bricks are a type of building material made through a special firing process. During the manufacturing process, combustible materials are incorporated into the brick and ignited at high temperatures to generate heat inside the brick, thereby promoting uniform sintering. This method improves firing efficiency, reduces energy consumption, and enhances the strength and durability of the brick. Due to their excellent performance and economy, internally combustible bricks are widely used in the exterior and interior walls of buildings, as well as in the paving of roads and sidewalks.
[0003] Packing sintered bricks involves stacking several bricks together. Brick clamps are often used during the stacking process, but these clamps require repeated adjustments during handling, which affects the continuity of sintered brick packing and reduces work efficiency. To address this, we propose a fully automatic unloading and packing device for internally sintered bricks. Utility Model Content
[0004] The purpose of this invention is to provide a fully automatic brick unloading and packaging device for internally sintered bricks. By setting a moving part, specifically moving the top rack to the right to rotate the gear, and then moving it to the left through the meshing connection between the gear and the bottom rack, the device moves the electric push rod through the L-shaped plate. This allows the gripping tool to be quickly positioned on top of the brick and gripped, and then the sintered brick is quickly moved to the vicinity of the packaging area, ensuring the continuity of sintered brick packaging and improving work efficiency. This solves the problem that existing sintered brick packaging involves stacking several bricks together, often using brick clamps during the stacking process. However, the brick clamps require repeated adjustments during handling, affecting the continuity of sintered brick packaging and reducing work efficiency.
[0005] To solve the above-mentioned technical problems, this utility model is achieved through the following technical solution:
[0006] This utility model is a fully automatic brick unloading and packaging device for internal combustion sintered bricks, including a moving part. The moving part is used to adjust the position of the gripping device left and right, so that the gripping device can grip the sintered bricks at the bottom of the moving part.
[0007] A clamping part is installed at the bottom center of the movable part, and the clamping part is used to clamp the sintered brick;
[0008] The left and right adjustment of the moving part is used to make the clamping part move the sintered brick.
[0009] Furthermore, the moving part includes a moving component, which is used to drive the clamp at the bottom to move in the horizontal direction;
[0010] A limiting component is installed on the top of the movable component, and the limiting component is used to limit the horizontal movement of the movable component;
[0011] The limiting component limits the movement of the moving component to prevent the moving component from deflecting and getting stuck during movement.
[0012] Furthermore, the clamping part includes a clamping assembly, which is installed at the bottom center of the movable assembly, and the clamping assembly is used to clamp the sintered brick from the front and the back.
[0013] A pallet assembly is disposed at the bottom right side of the movable assembly, and the pallet assembly is used to place the sintered bricks clamped by the clamping assembly;
[0014] The pallet assembly is used to provide stable support for sintered bricks and reduce the risk of sintered brick piles collapsing.
[0015] Furthermore, the moving component includes a rectangular top plate, with support legs installed on the left and right sides of the bottom of the rectangular top plate. A square hole groove is formed at the top center of the support legs, and an L-shaped plate is provided on the top of the square hole groove. Protrusions are installed on the top and bottom of the back of the L-shaped plate. An electric push rod is installed at the top center of the L-shaped plate. A gear housing is provided on the back of the L-shaped plate. A square hole groove is formed at the bottom of the front of the gear housing. A gear is rotatably connected to the center inside the gear housing. A rack is meshed with the top and bottom of the gear. The protrusion on the back of the L-shaped plate passes through the square hole groove and is installed on the front of the rack at the bottom.
[0016] By setting two support legs, support can be provided from the left and right sides of the bottom of the rectangular top plate, ensuring that the rectangular top plate can be kept horizontal.
[0017] The outer surface of the bottom protrusion on the back of the L-shaped plate is slidably connected to the inner surface of the gear housing, which is used to drive the L-shaped plate to move by the movement of the bottom rack.
[0018] Furthermore, the moving component includes two connecting blocks, which are mounted on the center of the outer surface of the back of the rack. A lead screw is threadedly connected to the center of the top connecting block, and a guide rod is slidably connected to the center of the bottom connecting block. The left and right ends of the lead screw extend outward through the gear housing and are rotatably connected. The left and right ends of the guide rod are mounted on the inner surface of the gear housing.
[0019] By setting a light rod, the bottom rack can be limited to prevent it from deflecting during movement and affecting the meshing connection between the two racks and the gear;
[0020] The lead screw is provided with a motor on its left side. The motor is mounted on the left side of the gear housing. The right output end of the motor is mounted on the left outer surface of the lead screw via a coupling. The connection between the lead screw and the motor is used to drive the lead screw to rotate via the motor.
[0021] Furthermore, the limiting component includes two slide grooves and a rectangular slide rail. The two slide grooves are respectively opened on the front and rear sides of the square hole groove. Sliders are slidably connected inside the two slide grooves. The two sliders are respectively installed on the front and back sides of the bottom of the L-shaped plate.
[0022] By setting a sliding connection between the slide groove and the slider, the L-shaped plate can be prevented from shaking when moving, so that the electric actuator can smoothly drive the sintered brick to move.
[0023] The limiting component also includes a rectangular slide rail and a conveyor belt. The rectangular slide rail is installed on the front side of the top of the gear housing, and the conveyor belt is located on the left side of the bottom of the rectangular top plate. The protrusion on the top of the back of the L-shaped plate is slidably connected to the rectangular slide rail. The rectangular slide rail is used to limit the L-shaped plate and prevent the top of the L-shaped plate from tilting forward.
[0024] Furthermore, the clamping assembly includes a clamping plate housing, which is installed at the center of the bottom output end of the electric actuator. Cylindrical slide rods are provided on the left and right sides of the top center inside the clamping plate housing. A bidirectional lead screw is provided at the bottom center of the two cylindrical slide rods. The front and back sides of the cylindrical slide rods are installed on the inner surface of the clamping plate housing. The cylindrical slide rods extend outward through the front and back sides of the clamping plate housing and are rotatably connected. Clamping plates are threaded onto the front and back sides of the outer surface of the clamping plate housing. Irregularly shaped slide rails are installed on the left and right sides of the outer surface of the clamping plate housing. Irregularly shaped sliders are slidably connected to the outer surface of the irregularly shaped slide rails. The sides of the two irregularly shaped sliders that are close to each other are installed on the outer surface of the side of the clamping plate. A second motor is provided on the back of the bidirectional lead screw. The second motor is installed on the outer surface of the back of the clamping plate housing. The front output end of the second motor is installed on the outer surface of the back of the bidirectional lead screw via a coupling.
[0025] By setting the connection between motor 2 and the bidirectional lead screw, motor 2 can control the rotation direction of the bidirectional lead screw through the output end, thereby controlling the clamping plate to grip and put down the sintered bricks.
[0026] The threads on the front and back of the bidirectional lead screw are mirror images of each other, which is used to drive the two clamping plates closer to or further apart by rotating the bidirectional lead screw.
[0027] Furthermore, the pallet assembly includes a rectangular pallet, which is disposed at the bottom center of the support leg on the left side. A rectangular protrusion is installed on the right side of the rectangular pallet, and inserts are installed on the front and back sides of the left side of the rectangular protrusion.
[0028] By setting the insertion relationship between the plug and the slot, the rectangular support plate can be positioned at the bottom center of the right support leg by inserting the plug into the slot.
[0029] The tray assembly further includes two slots, both of which are located on the outer surface of the left side of the support leg. The inner surface of the slot is inserted into and limited by the outer surface of the slot to prevent the rectangular tray from shifting during insertion.
[0030] This utility model has the following beneficial effects:
[0031] 1. This utility model, by setting a moving part, specifically moves the top rack to the right, causing the gear to rotate, and through the meshing connection between the gear and the bottom rack, moves it to the left, and drives the electric push rod to move through the L-shaped plate. In this way, the gripping tool can be quickly positioned on the top of the brick and the gripping can be completed. Then, the sintered brick can be quickly moved to the vicinity of the packaging area, ensuring the continuity of sintered brick packaging and improving work efficiency.
[0032] 2. This utility model, by setting up a clamping part, specifically starts the second motor, causing the bidirectional lead screw to rotate counterclockwise, driving the two clamping plates to move closer to each other along the cylindrical slide bar, and causing the clamping plates to slide along the irregular slide rail via the irregular slider. In this way, the sintered brick is gripped by the mutual approach of the two clamping plates, and moved horizontally with the assistance of the moving component, thus completing the packaging of the sintered brick.
[0033] Of course, any product implementing this utility model does not necessarily need to achieve all of the advantages described above at the same time. Attached Figure Description
[0034] To more clearly illustrate the technical solutions of the embodiments of this utility model, the accompanying drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0035] Figure 1 This is a schematic diagram of the overall front structure of this utility model;
[0036] Figure 2 This is a schematic diagram of the square hole groove structure of this utility model;
[0037] Figure 3 This is a schematic diagram of the rectangular top plate structure of this utility model;
[0038] Figure 4 This is a schematic diagram of the rack structure of this utility model;
[0039] Figure 5 This is a schematic diagram of the connecting block structure of this utility model;
[0040] Figure 6 This is a schematic diagram of the L-shaped plate structure of this utility model;
[0041] Figure 7 This is a schematic diagram of the irregularly shaped slider structure of this utility model;
[0042] Figure 8 This is a schematic cross-sectional view of the clamp shell of this utility model;
[0043] Figure 9 This is a schematic diagram of the rectangular tray structure of this utility model.
[0044] The attached diagram lists the components represented by each number as follows:
[0045] 1. Moving part; 11. Moving assembly; 111. Rectangular top plate; 112. Support leg; 113. Square hole slot one; 114. L-shaped plate; 115. Electric actuator; 1161. Gear housing; 1162. Square hole slot two; 1171. Gear; 1172. Rack; 118. Connecting block; 1191. Lead screw; 1192. Smooth rod; 1193. Motor one; 12. Limiting assembly; 121. Slide groove; 122. Slider; 123. Rectangular slide rail; 124. Conveyor belt; 2. Clamping part; 21. Clamping assembly; 211. Clamping plate housing; 2121. Cylindrical slide rod; 2122. Bidirectional lead screw; 213. Clamping plate; 214. Irregular slide rail; 215. Irregular slider; 216. Motor II; 22. Pallet assembly; 221. Rectangular pallet; 222. Rectangular protrusion; 223. Insert block; 224. Slot. Detailed Implementation
[0046] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the scope of protection of the present utility model.
[0047] Please see Figures 1-9 As shown, this utility model is a fully automatic brick unloading and packaging device for internal combustion sintered bricks, including a moving part 1. The moving part 1 is used to adjust the position of the gripping device left and right, so that the gripping device can grip the sintered bricks at the bottom of the moving part 1.
[0048] Clamping part 2 is installed at the bottom center of the moving part 1 and is used to clamp the sintered brick.
[0049] The left and right adjustment of the moving part 1 is used to enable the clamping part 2 to move the sintered brick.
[0050] The moving part 1 includes a moving component 11, which is used to drive the clamp at the bottom to move horizontally;
[0051] Limiting component 12 is installed on the top of the moving component 11 and is used to limit the horizontal movement of the moving component 11.
[0052] The limiting component 12 limits the moving component 11 to prevent the moving component 11 from deflecting and getting stuck during movement.
[0053] The clamping part 2 includes a clamping assembly 21, which is installed at the bottom center of the moving assembly 11. The clamping assembly 21 is used to clamp the sintered brick from the front and the back.
[0054] The pallet assembly 22 is located at the bottom right side of the moving assembly 11 and is used to place the sintered bricks held by the clamping assembly 21.
[0055] The pallet assembly 22 is used to provide stable support for the sintered bricks and reduce the risk of the sintered brick pile collapsing.
[0056] The moving component 11 includes a rectangular top plate 111. Support legs 112 are installed on the left and right sides of the bottom of the rectangular top plate 111. A square hole groove 113 is opened at the top center of the support leg 112. An L-shaped plate 114 is provided on the top of the square hole groove 113. A protrusion is installed on the top and bottom of the back of the L-shaped plate 114. An electric push rod 115 is installed at the top center of the L-shaped plate 114. A gear housing 1161 is provided on the back of the L-shaped plate 114. A square hole groove 1162 is opened at the bottom of the front of the gear housing 1161. A gear 1171 is rotatably connected to the center inside the gear housing 1161. A rack 1172 is meshed with the top and bottom of the gear 1171. The protrusion on the back of the L-shaped plate 114 passes through the square hole groove 1162 and is installed on the front of the rack 1172 at the bottom.
[0057] Move the top rack 1172 to the right to rotate the gear 1171, and move it to the left through the meshing connection between the gear 1171 and the bottom rack 1172. The L-shaped plate 114 drives the electric push rod 115 to move. This allows the gripping tool to be quickly positioned on the top of the brick and gripped. Then, the sintered brick is quickly moved to the vicinity of the packaging area to ensure the continuity of sintered brick packaging and improve work efficiency.
[0058] The outer surface of the bottom protrusion on the back of the L-shaped plate 114 is slidably connected to the inner surface of the gear housing 1161, which is used to drive the L-shaped plate 114 to move by the movement of the bottom rack 1172.
[0059] The moving component 11 includes two connecting blocks 118. The connecting blocks 118 are mounted on the center of the outer surface of the back of the rack 1172. A lead screw 1191 is threadedly connected to the center of the top connecting block 118, and a smooth rod 1192 is slidably connected to the center of the bottom connecting block 118. The left and right ends of the lead screw 1191 extend outward through the gear housing 1161 and are rotatably connected. The left and right ends of the smooth rod 1192 are mounted on the inner surface of the gear housing 1161.
[0060] The lead screw 1191 is provided with a motor 1193 on its left side. The motor 1193 is installed on the left side of the gear housing 1161. The right output end of the motor 1193 is installed on the left outer surface of the lead screw 1191 through a coupling. The connection between the lead screw 1191 and the motor 1193 is used to drive the lead screw 1191 to rotate through the motor 1193.
[0061] The limiting component 12 includes two slide grooves 121 and a rectangular slide rail 123. The two slide grooves 121 are respectively opened on the front and rear sides of the square hole groove 113. The two slide grooves 121 are slidably connected to the inside of each slide groove 121. The two slide rails 122 are respectively installed on the front and back sides of the bottom of the L-shaped plate 114.
[0062] The limiting component 12 also includes a rectangular slide rail 123 and a conveyor belt 124. The rectangular slide rail 123 is installed on the front side of the top of the gear housing 1161, and the conveyor belt 124 is located on the left side of the bottom of the rectangular top plate 111. The protrusion on the top of the back of the L-shaped plate 114 is slidably connected to the rectangular slide rail 123. The rectangular slide rail 123 is used to limit the L-shaped plate 114 and prevent the top of the L-shaped plate 114 from tilting forward.
[0063] The clamping assembly 21 includes a clamping plate housing 211, which is mounted at the center of the bottom output end of the electric actuator 115. Cylindrical slide rods 2121 are provided on the left and right sides of the top center of the interior of the clamping plate housing 211. A bidirectional lead screw 2122 is provided at the bottom center of the two cylindrical slide rods 2121. The front and back sides of the cylindrical slide rods 2121 are mounted on the inner surface of the clamping plate housing 211. The cylindrical slide rods 2121 extend outwards through the front and back sides of the clamping plate housing 211 and are rotatably connected. The outer surface of the clamping plate housing 211... Both the front and back sides are threaded with clamping plates 213. The left and right sides of the outer surface of the clamping plate housing 211 are equipped with irregular slide rails 214. Irregular sliders 215 are slidably connected to the outer surface of the irregular slide rails 214. The sides of the two irregular sliders 215 that are close to each other are installed on the outer surface of the side of the clamping plate 213. The back of the bidirectional lead screw 2122 is equipped with a second motor 216. The second motor 216 is installed on the outer surface of the back of the clamping plate housing 211. The front output end of the second motor 216 is installed on the outer surface of the back of the bidirectional lead screw 2122 through a coupling.
[0064] Start motor 216, causing bidirectional lead screw 2122 to rotate counterclockwise, driving two clamping plates 213 to move closer to each other along cylindrical slide bar 2121, and causing clamping plates 213 to slide along irregular slide rail 214 via irregular slider 215. In this way, the sintered brick is gripped by the mutual approach of the two clamping plates 213, and moved horizontally with the assistance of moving component 11 to complete the packaging of sintered bricks.
[0065] The threads on the front and back of the bidirectional lead screw 2122 are mirror images of each other, which is used to drive the two clamping plates 213 to move closer or further apart by rotating the bidirectional lead screw 2122.
[0066] The tray assembly 22 includes a rectangular tray 221, which is located at the bottom center of the support leg 112 on the left side. A rectangular protrusion 222 is installed on the right side of the rectangular tray 221, and an insert 223 is installed on the front and back sides of the left side of the rectangular protrusion 222.
[0067] The tray assembly 22 also includes two slots 224, both of which are opened on the outer surface of the left side of the support leg 112. The inner surface of the slot 224 is inserted into and limited by the outer surface of the slot 224 to prevent the rectangular tray 221 from shifting during insertion.
[0068] A specific application of this embodiment is as follows: When in use, first, insert the insert 223 into the inside of the slot 224, fix the rectangular tray 221 at the bottom center of the left support leg 112, then start the conveyor belt 124, and continuously arrange several processed sintered bricks in a row on the top left side of the conveyor belt 124, and then start the conveyor belt 124 to transport the sintered bricks to the right side through the conveyor belt 124;
[0069] Next, start motor 1193, which rotates counterclockwise to drive the top connecting block 118 to move the top rack 1172 to the right. Through the meshing connection between the two racks 1172 and the gear 1171, the bottom rack 1172 moves to the left along the outer surface of the smooth rod 1192 via the bottom connecting block 118. Through the fixed connection between the bottom rack 1172 and the back of the L-shaped plate 114, the L-shaped plate 114 moves to the left. The electric push rod 115 installed at the center of the L-shaped plate 114 drives the clamping plate housing 211 installed at the bottom to move, moving the clamping plate housing 211 to the top of the sintered brick.
[0070] Next, the electric actuator 115 is activated to move the clamping plate housing 211 downward and adjust it to a position that facilitates gripping the sintered bricks. Then, the motor 216 is activated to make the bidirectional lead screw 2122 rotate counterclockwise, causing the two clamping plates 213 to move closer to each other and move the clamping plates 213 along the cylindrical slide bar 2121. The irregularly shaped slider 215 moves along the irregularly shaped slide rail 214 to prevent the two clamping plates 213 from deflecting. By moving the two clamping plates 213 closer to each other, the sintered bricks placed on the conveyor belt 124 can be gripped.
[0071] Finally, start motor 1193. Motor 1193 rotates clockwise, causing the top connecting block 118 to move the top rack 1172 to the left. Through the meshing of the two racks 1172 with gear 1171, the bottom rack 1172 moves to the right along the outer surface of the smooth rod 1192 via the bottom connecting block 118. The bottom rack 1172, fixedly connected to the back of the L-shaped plate 114, moves the L-shaped plate 114 to the right, causing the electric push rod 115 installed at the center of the L-shaped plate 114 to move the bottom... The clamp housing 211 is moved to the top of the rectangular pallet 221. Then, the electric push rod 115 is activated to move the clamp housing 211 downward. Then, the clamp 213 is reset to place the sintered bricks on the top of the rectangular pallet 221. The sintered bricks are continuously stacked on the top of the rectangular pallet 221. When all the sintered bricks are stacked, the equipment is turned off, and the rectangular pallet 221 and the sintered bricks are wrapped with straps. Then, a forklift is used to move the packaged sintered bricks into the interior of the transport vehicle.
[0072] In the description of this specification, references to terms such as "an embodiment," "example," "specific example," etc., indicate that a specific feature, structure, material, or characteristic described in connection with that embodiment or example is included in at least one embodiment or example of the present invention. In this specification, the illustrative expressions of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the specific features, structures, materials, or characteristics described may be combined in any suitable manner in one or more embodiments or examples.
[0073] The preferred embodiments of this utility model disclosed above are merely illustrative of the present utility model. These preferred embodiments do not exhaustively describe all details, nor do they limit the present utility model to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of the present utility model, thereby enabling those skilled in the art to better understand and utilize it. This utility model is limited only by the claims and their full scope and equivalents.
Claims
1. A full-automatic unloading, packing device for internal combustion sintered bricks, characterized in that, include: The movable part (1) is used to adjust the position of the gripping device left and right, so that the gripping device can grip the sintered brick at the bottom of the movable part (1). Clamping part (2), the clamping part (2) is installed at the bottom center of the moving part (1), the clamping part (2) is used to clamp the sintered brick; The left and right adjustment of the moving part (1) is used to make the clamping part (2) move the sintered brick; The moving part (1) includes a moving component (11) for driving the clamp at the bottom to move horizontally; A limiting component (12) is installed on the top of the moving component (11) and is used to limit the horizontal movement of the moving component (11). The moving component (11) includes a rectangular top plate (111), with support legs (112) installed on the left and right sides of the bottom of the rectangular top plate (111). A square hole groove (113) is provided at the top center of the support leg (112), and an L-shaped plate (114) is provided on the top of the square hole groove (113). Protrusions are installed on the top and bottom of the back of the L-shaped plate (114), and an electric push rod (115) is installed at the top center of the L-shaped plate (114). The back of the L-shaped plate (114) is provided with a gear housing (1161). The bottom of the front of the gear housing (1161) is provided with a square hole groove (1162). A gear (1171) is rotatably connected to the center inside the gear housing (1161). The top and bottom of the gear (1171) are meshed with racks (1172). The protrusion on the back of the L-shaped plate (114) passes through the square hole groove (1162) and is installed on the front of the rack (1172) at the bottom. The outer surface of the bottom protrusion on the back of the L-shaped plate (114) is slidably connected to the inner surface of the gear housing (1161), which is used to drive the L-shaped plate (114) to move by the movement of the bottom rack (1172); The moving component (11) includes two connecting blocks (118), which are mounted on the center of the outer surface of the back of the rack (1172). A lead screw (1191) is threadedly connected to the center of the top connecting block (118), and a smooth rod (1192) is slidably connected to the center of the bottom connecting block (118). The left and right ends of the lead screw (1191) extend outward through the gear housing (1161) and are rotatably connected. The left and right ends of the smooth rod (1192) are mounted on the inner surface of the gear housing (1161). Among them, a motor (1193) is provided on the left side of the lead screw (1191). The motor (1193) is installed on the left side of the gear housing (1161). The right output end of the motor (1193) is installed on the left outer surface of the lead screw (1191) through a coupling. The connection between the lead screw (1191) and the motor (1193) is used to drive the lead screw (1191) to rotate through the motor (1193). The limiting component (12) limits the moving component (11) to prevent the moving component (11) from deflecting and getting stuck during movement.
2. A full automatic unloading, packing device for internal combustion fired baking bricks as claimed in claim 1 wherein, The clamping part (2) includes a clamping assembly (21), which is installed at the bottom center of the moving assembly (11) and is used to clamp the sintered brick from the front and back. The pallet assembly (22) is located at the bottom right side of the moving assembly (11) and is used to place the sintered bricks held by the clamping assembly (21). The pallet assembly (22) is used to provide stable support for sintered bricks and reduce the risk of sintered brick pile collapse.
3. A full automatic unloading, packing device for internal combustion fired bricks as claimed in claim 1 wherein, The limiting component (12) includes two slide grooves (121) and a rectangular slide rail (123). The two slide grooves (121) are respectively opened on the front and rear sides of the square hole groove (113). The two slide grooves (121) are slidably connected to the inside of each slide groove (122). The two slide rails (122) are respectively installed on the front and back sides of the bottom of the L-shaped plate (114). The limiting component (12) further includes a rectangular slide rail (123) and a conveyor belt (124). The rectangular slide rail (123) is installed on the front side of the top of the gear housing (1161), and the conveyor belt (124) is located on the left side of the bottom of the rectangular top plate (111). The protrusion on the top of the back of the L-shaped plate (114) is slidably connected to the rectangular slide rail (123). The rectangular slide rail (123) is used to limit the L-shaped plate (114) and prevent the top of the L-shaped plate (114) from tilting forward.
4. A full automatic unloading, packing device for internal combustion fired bricks as claimed in claim 2 wherein, The clamping assembly (21) includes a clamping plate housing (211), which is installed at the center of the bottom output end of the electric actuator (115). Cylindrical slide rods (2121) are provided on the left and right sides of the top center inside the clamping plate housing (211), and bidirectional lead screws (2122) are provided at the bottom center of the two cylindrical slide rods (2121).
5. A full automatic unloading, packing device for internal combustion fired baking bricks as claimed in claim 4 wherein, The front and back sides of the cylindrical slide rod (2121) are both mounted on the inner surface of the clamping plate shell (211). The cylindrical slide rod (2121) extends outward through the front and back sides of the clamping plate shell (211) and is rotatably connected. The front and back sides of the outer surface of the clamping plate shell (211) are threaded with clamping plates (213).
6. A full-automatic unloading, packing device for internal combustion fired bricks according to claim 5, characterized in that, The outer surface of the clamping plate housing (211) is equipped with irregular slide rails (214) on the left and right sides. Irregular sliders (215) are slidably connected to the outer surface of the irregular slide rails (214). The two irregular sliders (215) are installed on the outer surface of the side of the clamping plate (213) with their sides close to each other. A motor (216) is provided on the back of the bidirectional lead screw (2122).
7. The fully automatic brick unloading and packaging device for internally combusted bricks according to claim 6, characterized in that, The second motor (216) is mounted on the outer surface of the back of the clamping plate housing (211), and the front output end of the second motor (216) is mounted on the outer surface of the back of the double-acting lead screw (2122) via a coupling; The threads on the front and back of the bidirectional lead screw (2122) are mirror images of each other, which is used to drive the two clamps (213) to move closer or further apart by rotating the bidirectional lead screw (2122).
8. The fully automatic brick unloading and packaging device for internally combusted bricks according to claim 2, characterized in that, The pallet assembly (22) includes a rectangular pallet (221), which is located at the bottom center of the support leg (112) on the left side. A rectangular protrusion (222) is installed on the right side of the rectangular pallet (221), and an insert (223) is installed on the front and back sides of the left side of the rectangular protrusion (222). The tray assembly (22) further includes two slots (224), both of which are located on the outer surface of the left side of the support leg (112). The inner surface of the slot (224) is inserted into and limited by the outer surface of the slot (224) to prevent the rectangular tray (221) from shifting during insertion.