CN220741624U - Adobe pressing device - Google Patents

Abstract

The utility model relates to the technical field of green brick production, and particularly discloses a green brick pressing device. The green brick pressing device comprises a first press, a second press, a third press and a fourth press which are sequentially arranged side by side, and discharge conveying roller frames are arranged at discharge holes of the first press, the second press, the third press and the fourth press. Every ejection of compact conveying roller frame's side all is provided with a camera probe that is used for shooing the adobe image, and when the adobe from the in-process of moving on any switching-over unit on the ejection of compact conveying roller frame, the image of adobe is all shot to the camera probe. When the green bricks are unqualified, the controller controls the corresponding presses to stop working, and the pressing speed of the other three presses is accelerated, so that the green bricks in the kiln are sufficiently fed.

Description

Adobe pressing device

Technical Field

The utility model relates to the field of green brick production, in particular to a green brick pressing device.

Background

In the existing green brick production line, a kiln is generally fed through four presses, and the four presses can press different or same products, continuously discharge materials to maintain the kiln full, and further ensure the quality of ceramic drying. However, the press may malfunction during the production process, and when one of the four presses malfunctions, such as a defect in the mold of one press, the green bricks pressed by the press will have defects. The existing green brick conveyor belt cannot screen out defective green bricks, and if the defective green bricks enter the kiln, the energy of the kiln is consumed. If the part of defective green bricks do not enter the kiln, the feeding amount of the kiln is reduced, the kiln cannot be kept full, the temperature in the kiln is increased, the temperature of the green bricks exceeds the preset temperature during drying, and the green bricks deform.

Disclosure of Invention

The utility model discloses a green brick pressing device which is used for solving the problem that a kiln cannot be maintained full due to press faults.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

an green brick pressing apparatus comprising:

the device comprises a first press, a second press, a third press and a fourth press which are sequentially arranged side by side, wherein discharge ports of the first press, the second press, the third press and the fourth press are respectively provided with a discharge conveying roller frame;

the first reversing unit, the second reversing unit, the third reversing unit and the fourth reversing unit are respectively and sequentially arranged at the downstream of the discharging and conveying roller frames of the first press, the second press, the third press and the fourth press, and are used for changing the conveying direction of green bricks;

the first reversing unit comprises a first bracket, a plurality of feeding rollers are arranged on the first bracket, two reversing structures are arranged below the feeding rollers, and the reversing structures are used for changing the conveying direction of green bricks;

the shooting probes with the same number as the discharge conveying roller frames are arranged beside the discharge conveying roller frames and are used for shooting green brick images;

a first transfer structure disposed between the first reversing unit and the second reversing unit;

a second transfer structure disposed between the second reversing unit and the third reversing unit;

a third transfer structure disposed between the third reversing unit and the fourth reversing unit;

a fourth conveying structure disposed downstream of the fourth reversing unit;

and the controller is used for being electrically connected with the first press, the second press, the third press, the fourth press, the camera probe, the first reversing unit, the second reversing unit, the third reversing unit and the fourth reversing unit.

Preferably, the reversing structure comprises a mounting seat, an air cylinder is arranged on the mounting seat, a mounting plate is mounted at the output end of the air cylinder, a supporting rod and a conveying belt are arranged on the mounting plate, and the air cylinder is used for driving the conveying belt to move up and down through a gap between adjacent feeding rollers.

Preferably, the first bracket comprises a first portion and a second portion, the first portion having a height that is lower than a height of the second portion.

Preferably, the first conveying structure, the second conveying structure, the third conveying structure and the fourth conveying structure are identical in structure;

the first conveying structure comprises a first conveying roller frame and a second conveying roller frame, the first conveying roller frame is adjacently arranged at the side of the second conveying roller frame, one end of the first conveying roller frame is connected with the first reversing unit, the other end of the first conveying roller frame is connected with the second reversing unit, one end of the second conveying roller frame is connected with the first reversing unit, and the other end of the second conveying roller frame is connected with the second reversing unit.

Preferably, the first reversing unit further comprises a first baffle and a first motor, the first baffle is rotatably connected to the first bracket, the first motor is mounted on the first bracket, and the first motor is used for driving the first baffle to rotate.

Preferably, the first reversing unit further comprises a second baffle, the second baffle is installed on the first bracket, and the second baffle is used for stopping green bricks.

Preferably, the second reversing unit comprises a second bracket, a plurality of feeding rollers are arranged on the second bracket, two reversing structures are arranged below the feeding rollers, and the reversing structures are used for changing the conveying direction of the green bricks.

Preferably, the second bracket comprises a third part and a fourth part, and the height of the third part and the fourth part is lower than the upper surface of the feeding roller on the second bracket.

Preferably, the second reversing unit further comprises a third baffle and a second motor, the third baffle is rotatably connected to the second bracket, the third baffle is arranged between the first conveying roller frame and the second conveying roller frame, the second motor is mounted on the second bracket, and the second motor is used for driving the third baffle to rotate.

Preferably, the second reversing unit further comprises a fourth baffle, the fourth baffle is mounted on the second bracket, and the fourth baffle is used for stopping green bricks.

Compared with the prior art, the utility model has the beneficial effects that:

according to the green brick pressing device provided by the utility model, the image of the green brick can be shot through the shooting probe, the image information is fed back to the controller, and the controller compares the shot image with the pre-stored image, so that whether the green brick is pressed is qualified or not is judged. When the green bricks are qualified, the feeding roller on the first bracket conveys the green bricks for a first distance, the green bricks are conveyed to the upper part of a reversing structure, then the green bricks are conveyed to a first conveying structure through the reversing structure, and the qualified green bricks are conveyed into the kiln through the first conveying structure. And when the green bricks are unqualified, the feeding roller on the first bracket conveys the green bricks by a second distance, the green bricks are conveyed to the upper part of another reversing structure, then the green bricks are conveyed to the first conveying structure through the reversing structure, and the first conveying structure conveys the unqualified green bricks to the recycling position. Similarly, the second press, the third press and the fourth press all operate with the same logic as the first press.

Meanwhile, when the defect of the press on the rear surface of the unqualified green brick is detected, the controller controls the press to stop working, and meanwhile, the controller controls the three remaining presses to work at a faster pressing speed, for example, the green brick is pressed at 75% of the pressing speed in the initial state of four presses, and when one press fails, the pressing speed of the three remaining presses is increased to 100% so as to meet the feeding requirement of a kiln.

Drawings

FIG. 1 is a schematic diagram of a green brick pressing apparatus according to an embodiment of the present utility model;

fig. 2 is a schematic structural diagram of a first reversing unit and a first conveying structure according to an embodiment of the present utility model;

fig. 3 is a schematic structural diagram of a first reversing unit according to an embodiment of the present utility model;

fig. 4 is an exploded view of a first reversing unit according to an embodiment of the present utility model;

FIG. 5 is an enlarged view of a portion of the structure of FIG. 4;

fig. 6 is a schematic structural diagram of a second reversing unit according to an embodiment of the utility model.

Description of main reference numerals: 10 a-first press, 10 b-second press, 10 c-third press, 10 d-fourth press, 20-first reversing unit, 21-first carriage, 211-first section, 212-second section, 22-feed roll, 23-reversing arrangement, 231-mount, 232-cylinder, 233-mounting plate, 234-strut, 235-conveyor belt, 24-first baffle, 25-first motor, 26-second baffle, 20 a-second reversing unit, 21 a-second carriage, 211 a-third section, 212 a-fourth section, 22 a-third baffle, 23 a-second motor, 24 a-fourth baffle, 20 b-third reversing unit, 20 c-fourth reversing unit, 30-camera probe, 40-first conveying arrangement, 41-first conveying roller frame, 42-second conveying roller frame, 40 a-second conveying arrangement, 41 a-third conveying roller frame, 41 b-fourth conveying roller frame, 40 b-third conveying arrangement, 40 a-fourth conveying arrangement, 40 c-fourth conveying arrangement, 60-fourth conveyor frame.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In the present utility model, the terms "upper", "lower", "left", "right", "front", "rear", "top", "bottom", "inner", "outer", "middle", "vertical", "horizontal", "lateral", "longitudinal" and the like indicate an azimuth or a positional relationship based on that shown in the drawings. These terms are only used to better describe the present utility model and its embodiments and are not intended to limit the scope of the indicated devices, elements or components to the particular orientations or to configure and operate in the particular orientations.

Also, some of the terms described above may be used to indicate other meanings in addition to orientation or positional relationships, for example, the term "upper" may also be used to indicate some sort of attachment or connection in some cases. The specific meaning of these terms in the present utility model will be understood by those of ordinary skill in the art according to the specific circumstances.

Furthermore, the terms "mounted," "configured," "provided," "connected," and "connected" are to be construed broadly. For example, it may be a fixed connection, a removable connection, or a unitary construction; may be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements, or components. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

Furthermore, the terms "first," "second," and the like, are used primarily to distinguish between different devices, elements, or components (the particular species and configurations may be the same or different), and are not used to indicate or imply the relative importance and number of devices, elements, or components indicated. Unless otherwise indicated, the meaning of "a plurality" is two or more.

The technical scheme of the utility model will be further described with reference to the examples and the accompanying drawings.

Examples

In the existing green brick production line, a kiln is generally fed through four presses, and the presses may malfunction in the green brick pressing process, so that the presses cannot normally push out pressed green bricks onto a conveying structure, or a die for green brick pressing is damaged.

When the green bricks cannot be pushed out onto the conveying structure, the total amount of green bricks entering the kiln will be reduced, and the temperature in the kiln will be higher than the preset temperature, resulting in deformation of the green bricks during the drying process. If the green bricks are pushed into the kiln in case of breakage or other forms of defects, the green bricks need to be screened out after drying, and the partially defective green bricks waste the heat energy of the kiln.

The present application thus provides a green brick pressing apparatus, referring to fig. 1, which includes a first press 10a, a second press 10b, a third press 10c and a fourth press 10d arranged side by side in order, and discharge conveyor roller frames 60 are provided at discharge ports of the first press 10a, the second press 10b, the third press 10c and the fourth press 10 d. One end of each discharge and transport roller frame 60 downstream is provided with a first reversing unit 20, a second reversing unit 20a, a third reversing unit 20b and a fourth reversing unit 20c, namely a first reversing unit 20, a second reversing unit 20a, a third reversing unit 20b and a fourth reversing unit 20c, which are sequentially arranged downstream of the discharge and transport roller frames 60 of the first press 10a, the second press 10b, the third press 10c and the fourth press 10d, respectively. The four reversing units are used for changing the conveying direction of the green bricks.

Referring to fig. 2 and 3, the first reversing unit 20 includes a first bracket 21, a plurality of feeding rollers 22 are disposed on the first bracket 21, two reversing structures 23 are disposed below the feeding rollers 22, and the reversing structures 23 are used for changing the conveying direction of the green bricks. Each of the discharging and conveying roller frames 60 is provided with a camera probe 30 for shooting images of green bricks, and the camera probes 30 shoot images of green bricks when the green bricks move from the discharging and conveying roller frames 60 to any reversing unit.

Referring to fig. 1, in order to enable the green bricks transferred at the first, second, third and fourth presses 10a, 10b, 10c and 10d to be transferred onto one transfer roller and into the kiln, a first transfer structure 40 is provided between the first and second reversing units 20, 20a, a second transfer structure 40a is provided between the second and third reversing units 20a, 20b, a third transfer structure 40b is provided between the third and fourth reversing units 20b, 20c, and a fourth transfer structure 40c is provided downstream of the second reversing unit. The first conveying structure 40, the second conveying structure 40a, the third conveying structure 40b, the fourth conveying structure 40c, the first reversing unit 20, the second reversing unit 20a, the third reversing unit 20b and the fourth reversing unit 20c form a longer conveying line, and qualified green bricks are conveyed into the kiln.

Referring to fig. 1, the production line further includes a controller 50, and the controller 50 is configured to be electrically connected to the first press 10a, the second press 10b, the third press 10c, the fourth press 10d, the camera probe 30, the first reversing unit 20, the second reversing unit 20a, the third reversing unit 20b, and the fourth reversing unit 20 c.

Specifically, when any one of the imaging probes 30 no longer captures image information of the green brick within a set time, the controller 50 determines that the press corresponding to the imaging probe 30 is malfunctioning and no green brick is transmitted. Since the first press 10a, the second press 10b, the third press 10c and the fourth press 10d press green bricks only at 75% of the fastest pressing speed of the presses in normal operation, when any one of the presses fails, the controller 50 controls the press to stop working, and controls the remaining presses to press green bricks at 100% of the pressing speed, so that the number of green bricks entering the kiln can meet the requirement, and the temperature in the kiln cannot be higher.

When any one of the image pickup probes 30 photographs the green brick and the green brick photograph stored in the controller 50 are not identical (there is a defect), that is, the green brick is failed, the controller 50 similarly controls the press for transferring the failed green brick to stop working, and transfers the failed green brick to the recycling position through the cooperation of the reversing unit and the transfer structure.

Specifically, the first conveying structure 40, the second conveying structure 40a, the third conveying structure 40b, and the fourth conveying structure 40c are identical in structure. Referring to fig. 1 and 2, the first transfer member structure includes a first transfer roller frame 41 and a second transfer roller frame 42, the first transfer roller frame 41 is adjacently disposed at a side of the second transfer roller frame 42, one end of the first transfer roller frame 41 is connected with the first reversing unit 20, the other end of the first transfer roller frame 41 is connected with the second reversing unit 20a, one end of the second transfer roller frame 42 is connected with the first reversing unit 20, and the other end of the second transfer roller frame 42 is connected with the second reversing unit 20 a.

Referring to fig. 2, 3 and 4, the first reversing unit 20 includes a first bracket 21, and a plurality of feed rollers 22 are provided on the first bracket 21. Two reversing structures 23 are arranged below the feeding roller 22, the reversing structures 23 are used for changing the conveying direction of the green bricks, and the reversing structures 23 are used for rotating the conveying direction of the green bricks by 90 degrees in combination with fig. 1.

The reversing structure 23 comprises a mounting seat 231, a cylinder 232 is arranged on the mounting seat 231, a mounting plate 233 is arranged at the output end of the cylinder 232, a supporting rod 234 and a conveying belt 235 driven by a motor are arranged on the mounting plate 233, and the cylinder 232 is used for driving the conveying belt 235 to move up and down through a gap between adjacent feeding rollers 22.

Referring to fig. 3 and 4, when the green bricks pressed by the press are normal green bricks, the feeding roller 22 on the first support 21 conveys the normal green bricks to a first distance, that is, the conveying roller of the first support 21 conveys the normal green bricks to a position corresponding to the first conveying roller frame 41, and then the reversing structure 23 corresponding to the first conveying roller frame 41 works, the output end of the cylinder 232 of the reversing structure 23 stretches to drive the conveying belt 235 to rise, and the green bricks are driven to move onto the first conveying roller frame 41 under the driving action of the conveying belt 235.

When the image signal fed back by the camera probe 30 to the controller 50 is not matched with the preset image signal, the feeding roller 22 on the first bracket 21 will transmit the second distance, that is, the transmission roller of the first bracket 21 will transmit the normal green brick to the position corresponding to the second transmission roller frame 42, and then stop transmitting the green brick, at this time, the reversing structure 23 corresponding to the second transmission roller frame 42 works, the output end of the cylinder 232 of the reversing structure 23 stretches to drive the transmission belt 235 to rise, and the green brick is driven to move to the second transmission roller frame 42 under the driving action of the transmission belt 235.

Of course, in one embodiment of the present utility model, both the first transfer roller and the second transfer roller frame 42 are driven by a motor.

Further, in an embodiment of the present utility model, the first support 21 includes a first portion 211 and a second portion 212, wherein the first portion 211 of the first support 21 is higher than the second portion 212 of the first support 21, that is, the second portion 212 has a height lower than the upper surface of the feeding roller 22 in order to facilitate the transfer of the green bricks from the first reversing unit 20 to the first conveying structure 40, as shown in connection with fig. 2 and 3. While the first portion 211 has a height higher than the upper surface of the feed roller 22 to guide the green bricks.

The first reversing unit 20 further includes a first baffle 24 and a first motor 25, the first baffle 24 is rotatably connected to the first bracket 21, the first motor 25 is mounted on the first bracket 21, and the first baffle 24 is driven to rotate by the first motor 25. The first baffle 24 is used to block the green bricks.

Preferably, referring to fig. 2 and 5, in an embodiment of the present utility model, the first baffle 24 is disposed between the first conveying roller frame 41 and the second conveying roller frame 42, and the first baffle 24 is disposed between the two feed rollers 22.

Specifically, the first baffle 24 is in a normal blocking state, that is, in a state that the produced green bricks are normal, the first baffle 24 is in a standing state as shown in fig. 5, a first pressure sensor is arranged on the first baffle 24, when the green bricks move a first distance to strike the first baffle 24, the first pressure sensor is triggered, at this time, the reversing structure 23 corresponding to the first conveying roller frame 41 works, and the belt rises to convey the green bricks onto the first conveying roller frame 41.

When the conveyed green bricks have defects, the first motor 25 drives the first baffle plate 24 to rotate, the defective green bricks are conveyed to pass through the upper part of the first baffle plate 24, after the defective green bricks move for a second distance, the reversing structure 23 corresponding to the second conveying roller frame 42 works, the output end of the air cylinder 232 of the reversing structure 23 stretches to drive the conveying belt 235 to ascend, and the green bricks are driven to move to the second conveying roller frame 42 under the driving action of the conveying belt 235.

Further, in an embodiment of the present utility model, the first reversing unit 20 further includes a second baffle 26, where the second baffle 26 is mounted on the first bracket 21, and the second baffle 26 is used for stopping green bricks.

The defective green bricks are stopped by the second shutter 26 during the conveyance by the feed roller 22 on the first carriage 21. After the green bricks stop, the reversing structure 23 corresponding to the second conveying roller frame 42 works, and the output end of the air cylinder 232 of the reversing structure 23 stretches to drive the conveying belt 235 to ascend, so that the green bricks are driven to move onto the second conveying roller frame 42 under the driving action of the conveying belt 235.

Of course, a second pressure sensor may be further disposed on the second baffle 26, and the pressure sensor may be used to more accurately feed back the position information of the green brick.

The second reversing unit 20a, the third reversing unit 20b and the fourth reversing unit 20c have the same structure, the second reversing unit 20a comprises a second bracket 21a, a plurality of feeding rollers 22 are arranged on the second bracket 21a, two reversing structures 23 are arranged below the plurality of feeding rollers 22 in the same way, and the reversing structures 23 are used for changing the conveying direction of the green bricks.

As shown in fig. 6, the second bracket 21a includes a third portion 211a and a fourth portion 212a, and the heights of the third portion 211a and the fourth portion 212a are each lower than the upper surface of the feed roller 22 on the second bracket 21 a. Thereby enabling the green bricks on the first transfer structure 40 to smoothly move onto the second support 21 a. Similarly, the green bricks on the second support 21a can be smoothly transferred onto the second transfer structure 40 a.

In an embodiment of the present utility model, the reversing structures 23 on the second reversing unit 20a, the third reversing unit 20b and the fourth reversing unit 20c are identical to the reversing structures 23 on the first reversing unit 20, so that the reversing structures 23 on the second reversing unit 20a, the third reversing unit 20b and the fourth reversing unit 20c will not be described again.

Preferably, in an embodiment of the present utility model, the second reversing unit 20a further includes a third baffle 22a and a second motor 23a, the third baffle 22a is rotatably connected to the second bracket 21a, and the third baffle 22a is driven to rotate by the second motor 23 a. The first baffle 24 is used to block the green bricks.

Preferably, referring to fig. 1 and 6, in an embodiment of the present utility model, the first baffle 24 is disposed between the third conveying roller frame and the fourth conveying roller frame, and the third baffle 22a is disposed between the two feeding rollers 22 on the second bracket 21 a.

Similarly, the third baffle 22a and the first baffle 24 have the same working principle, the third baffle 22a is in a normal stop state, that is, under the condition that the produced green bricks are normal, the third baffle 22a is in a standing state as shown in fig. 6, a third pressure sensor is arranged on the third baffle 22a, when the green bricks move by a first distance to strike the third baffle 22a, the third pressure sensor is triggered, at this time, a reversing structure 23 corresponding to the third conveying roller frame works, and the belt rises to convey the green bricks onto the third conveying roller frame.

When the conveyed green bricks have defects, the second motor 23a drives the third baffle 22a to rotate, the defective green bricks are conveyed to pass through the upper part of the third baffle 22a, after the defective green bricks move for a second distance, the reversing structure 23 corresponding to the fourth conveying roller frame works, the output end of the air cylinder 232 of the reversing structure 23 stretches to drive the conveying belt 235 to ascend, and the defective green bricks are driven to move to the fourth conveying roller frame under the driving action of the conveying belt 235.

Further, in an embodiment of the present utility model, the second reversing unit 20a further includes a fourth baffle 24a, where the fourth baffle 24a is mounted on the second bracket 21a, and the fourth baffle 24a is used for stopping green bricks.

The defective green bricks are stopped by the fourth shutter 24a during the conveyance by the feed roller 22 on the second carriage 21 a. After the green bricks stop, the reversing structure 23 corresponding to the fourth conveying roller frame works, and the output end of the air cylinder 232 of the reversing structure 23 stretches to drive the conveying belt 235 to ascend, so that the green bricks are driven to move to the fourth conveying roller frame under the driving action of the conveying belt 235.

Further, a fourth pressure sensor may be further disposed on the fourth baffle 24a, and the position information of the green brick may be fed back more accurately through the pressure sensor.

Of course, in order for the upstream green bricks to pass through the second reversing unit 20a, the third reversing unit 20b, and the fourth reversing unit 20c without the feed rollers 22 being interfered, the conveyor belt at the corresponding reversing unit should be positioned above the feed rollers 22 so that the green bricks can pass through the second reversing unit, the third reversing unit, and the fourth reversing unit smoothly.

It will be understood that equivalents and modifications will occur to those skilled in the art based on the present utility model and its spirit, and all such modifications and substitutions are intended to be included within the scope of the present utility model.

Claims (10)

1. An green brick pressing apparatus, comprising:

the device comprises a first press, a second press, a third press and a fourth press which are sequentially arranged side by side, wherein discharge ports of the first press, the second press, the third press and the fourth press are respectively provided with a discharge conveying roller frame;

the first reversing unit, the second reversing unit, the third reversing unit and the fourth reversing unit are respectively and sequentially arranged at the downstream of the discharging and conveying roller frames of the first press, the second press, the third press and the fourth press, and are used for changing the conveying direction of green bricks;

the first reversing unit comprises a first bracket, a plurality of feeding rollers are arranged on the first bracket, two reversing structures are arranged below the feeding rollers, and the reversing structures are used for changing the conveying direction of green bricks;

the shooting probes with the same number as the discharge conveying roller frames are arranged beside the discharge conveying roller frames and are used for shooting green brick images;

a first transfer structure disposed between the first reversing unit and the second reversing unit;

a second transfer structure disposed between the second reversing unit and the third reversing unit;

a third transfer structure disposed between the third reversing unit and the fourth reversing unit;

a fourth conveying structure disposed downstream of the fourth reversing unit;

and the controller is used for being electrically connected with the first press, the second press, the third press, the fourth press, the camera probe, the first reversing unit, the second reversing unit, the third reversing unit and the fourth reversing unit.

2. The green brick pressing device according to claim 1, wherein the reversing structure comprises a mounting seat, a cylinder is arranged on the mounting seat, a mounting plate is arranged at the output end of the cylinder, a supporting rod and a conveyor belt are arranged on the mounting plate, and the cylinder is used for driving the conveyor belt to move up and down through a gap between adjacent feeding rollers.

3. The green brick pressing apparatus of claim 1 wherein the first support comprises a first portion and a second portion, the first portion having a height that is lower than a height of the second portion.

4. The green brick pressing apparatus of claim 1 wherein the first, second, third, and fourth conveying structures are identical in structure;

the first conveying structure comprises a first conveying roller frame and a second conveying roller frame, the first conveying roller frame is adjacently arranged at the side of the second conveying roller frame, one end of the first conveying roller frame is connected with the first reversing unit, the other end of the first conveying roller frame is connected with the second reversing unit, one end of the second conveying roller frame is connected with the first reversing unit, and the other end of the second conveying roller frame is connected with the second reversing unit.

5. The green brick pressing apparatus of claim 4, wherein the first reversing unit further comprises a first baffle rotatably connected to the first bracket, and a first motor mounted to the first bracket for driving the first baffle to rotate.

6. The green brick pressing apparatus of claim 4 or 5, wherein the first reversing unit further comprises a second baffle mounted on the first bracket, the second baffle being for stopping green bricks.

7. The green brick pressing apparatus of claim 4, wherein the second reversing unit comprises a second bracket, a plurality of feeding rollers are arranged on the second bracket, and two reversing structures are arranged below the feeding rollers and used for changing the conveying direction of the green bricks.

8. The green brick pressing apparatus of claim 7 wherein the second support comprises a third section and a fourth section, each of the third section and the fourth section having a height below an upper surface of a feed roller on the second support.

9. The green brick pressing apparatus according to claim 7 or 8, wherein the second reversing unit further comprises a third baffle rotatably connected to the second bracket, the third baffle being disposed between the first conveying roller frame and the second conveying roller frame, and a second motor mounted to the second bracket, the second motor being configured to drive the third baffle to rotate.

10. The green brick pressing apparatus of claim 7, wherein the second reversing unit further comprises a fourth baffle mounted on the second bracket, the fourth baffle for stopping green bricks.