CN112919166A - Corrugated box is with convenient type lithography apparatus - Google Patents

Abstract

The invention belongs to the technical field of printing equipment, and particularly relates to convenient printing equipment for a corrugated case, which adopts the technical scheme that: the automatic feeding device comprises a material pushing device, a feeding device and a flattening device, wherein the feeding device is arranged on the right side of the material pushing device, the flattening device is arranged on the right side of the feeding device, printing equipment is arranged on the right side of the flattening device, and the bottoms of the material pushing device, the feeding device and the flattening device are fixedly arranged on a supporting plate; the material pushing device comprises a first transmission assembly, a servo motor and a first supporting table, and the material pushing device has the beneficial effects that: by arranging the material pushing device and the material feeding device, the corrugated case is not required to be manually placed on the printing equipment, printing and feeding are automatically completed, the feeding speed is high, the labor cost is saved, and the printing speed and efficiency are improved; through setting up feedway to feedway and blevile of push share a servo motor, make the device structure simplify, saved the energy consumption, improved the transmission precision.

Description

Corrugated box is with convenient type lithography apparatus

Technical Field

The invention relates to the technical field of printing equipment, in particular to convenient printing equipment for corrugated cartons.

Background

The corrugated paper board is made into a corrugated paper box through die cutting, indentation, box nailing or box gluing, the corrugated paper box is a packaging product with the widest application, and the consumption is always the first of various packaging products; the corrugated case has replaced the transport packaging containers such as wooden cases and the like gradually with excellent service performance and good processing performance, and becomes the main force of transport packaging for more than half a century; the corrugated carton is a green product, is beneficial to environmental protection and loading, unloading and transportation.

The existing corrugated board printing machine puts the corrugated board into the printing machine in a manual mode, and the printing mode has low efficiency, low printing speed, large labor waste and high cost; and in the printing process, the corrugated board is uneven, so that the printing quality is poor.

Therefore, the invention is necessary to provide a convenient printing device for corrugated cartons.

Disclosure of Invention

Therefore, the invention provides the convenient printing equipment for the corrugated case, the material pushing device and the material feeding device are arranged, the corrugated boards which are overlapped together are automatically pushed into the flattening device one by one, the printing speed is increased, the corrugated boards are flattened by the flattening device, the printing quality is ensured, and the problems of low efficiency, low printing speed and poor printing quality of the existing corrugated board printing machine are solved.

In order to achieve the above purpose, the invention provides the following technical scheme:

a convenient printing device for corrugated cartons comprises a material pushing device, a feeding device and a flattening device, wherein the feeding device is arranged on the right side of the material pushing device, the flattening device is arranged on the right side of the material feeding device, the printing device is arranged on the right side of the flattening device, and the bottoms of the material pushing device, the feeding device and the flattening device are fixedly arranged on a supporting plate;

the material pushing device comprises a first transmission component, a servo motor and a first supporting platform, the first transmission component comprises a first hammer-shaped gear, a second supporting plate, a first vertical shaft, a third hammer-shaped gear, a fourth hammer-shaped gear, a first supporting plate, a transverse shaft, a fifth hammer-shaped gear, a sixth hammer-shaped gear and a second vertical shaft, the first hammer-shaped gear is meshed with the second hammer-shaped gear, the inner wall of the second hammer-shaped gear is sleeved with the first vertical shaft, one end, far away from the second hammer-shaped gear, of the first vertical shaft is sleeved with the third hammer-shaped gear, the third hammer-shaped gear is meshed with the fourth hammer-shaped gear, the inner wall of the fourth hammer-shaped gear is sleeved with the transverse shaft, the outer wall of the left end of the transverse shaft is sleeved with the fifth hammer-shaped gear, the fifth hammer-shaped gear is meshed with the sixth hammer-shaped gear, the inner wall of the sixth hammer-shaped gear is sleeved with the second, an ejector rod is inserted into the inner wall of the traction block, one end of the ejector rod is fixedly connected with a pull block, one end of the pull block is fixedly connected with a tension spring, and one end of the tension spring is fixedly connected with an auxiliary rod;

the feeding device comprises an object stage, a corrugated board is arranged on the object stage, a ring gear is fixedly installed at the bottom of the object stage, the bottom of the object stage is fixedly connected with a rotating shaft through a bearing, one end, far away from the object stage, of the rotating shaft is fixedly connected with a second supporting plate through a bearing, the ring gear is meshed with a driving wheel, the outer wall of the driving wheel is sleeved with the output end of a stepping motor, the bottoms of the second supporting plate are fixedly connected with supporting blocks through bolts, the bottoms of the supporting blocks are movably connected with upper inclined rods through mounting blocks, one ends, far away from the supporting blocks, of the upper inclined rods are fixedly connected with driving nuts through the mounting blocks, the bottoms of the driving nuts are fixedly connected with lower inclined rods;

the flattening device comprises a limiting plate, the inner wall of the limiting plate is fixedly connected with a shaft rod through a bearing, the outer wall of the shaft rod is sleeved with a flattening wheel, a conveying belt is arranged below the flattening wheel, the outer wall of the shaft rod is sleeved with a seventh hammer-shaped gear, the seventh hammer-shaped gear is meshed with an eighth hammer-shaped gear, the eight inner wall of the hammer-shaped gear is sleeved with a third vertical shaft, the third vertical shaft is far away from the outer wall of one end of the eighth hammer-shaped gear, and the ninth hammer-shaped gear is sleeved with a ninth hammer-shaped gear, and the ninth.

Preferably, the screw rod is sleeved on the inner wall of the hammer-shaped gear, and the output end of the servo motor is fixedly connected with the screw rod.

Preferably, the outer wall of the vertical shaft II is fixedly connected with a first supporting platform through a bearing, a first supporting plate is fixedly installed at the bottom of the first supporting platform, and one end, far away from the first supporting platform, of the first supporting plate is fixedly connected with the horizontal shaft through a bearing.

Preferably, the stepping motor is fixedly installed on the second supporting plate, and the installation block at the bottom end of the lower inclined rod is fixedly installed on the supporting plate.

Preferably, the outer wall of the screw rod is fixedly connected with a support column through a bearing, and the bottom of the support column is fixedly installed on the support plate.

Preferably, the screw rod is sleeved on the ten inner walls of the hammer-shaped gear, the screw rod is sleeved on the one inner wall of the hammer-shaped gear, and the three outer walls of the vertical shaft are fixedly connected with the fixing plate through bearings.

Preferably, one end of the object stage is fixedly connected with a sleeve, the inner wall of the sleeve is inserted with a sleeve rod, and the outer surface of the sleeve is fixedly connected with a baffle.

Preferably, the supporting legs are fixedly installed at the bottom of the first supporting platform, the outer wall of the first vertical shaft is fixedly connected with the second supporting plate through a bearing, and one end of the second supporting plate is fixedly installed on the first supporting platform.

Preferably, the shape and the structure of the first hammer-shaped gear, the second hammer-shaped gear, the third hammer-shaped gear, the fourth hammer-shaped gear, the fifth hammer-shaped gear and the sixth hammer-shaped gear are the same, and the bottom end of the auxiliary rod is fixedly connected with the first support platform.

Preferably, the screw rod is connected with a second transmission assembly in a transmission mode, the second transmission assembly comprises a main belt pulley, a belt, a secondary belt pulley, a first supporting plate, a transverse shaft, a fifth hammer-shaped gear, a sixth hammer-shaped gear and a second vertical shaft, the main belt pulley is connected with a secondary belt pulley through belt transmission, and the inner wall of the secondary belt pulley is sleeved with the transverse shaft.

The invention has the beneficial effects that:

1. by arranging the material pushing device and the material feeding device, the corrugated case is not required to be manually placed on the printing equipment, printing and feeding are automatically completed, the feeding speed is high, the labor cost is saved, and the printing speed and efficiency are improved;

2. by arranging the feeding device, and sharing one servo motor with the material pushing device, the device has a simplified structure, saves energy consumption and improves transmission precision; when the uppermost corrugated board is input to the conveyer belt, the objective table in the feeding device is jacked up, and feeding is automatically completed;

3. by arranging the flattening device, the corrugated board to be conveyed is flattened, so that printing in printing equipment is facilitated, and the printing quality is improved;

4. the flattening device and the material pushing device also share the servo motor, so that the structure of the device is further simplified, later maintenance and repair are facilitated, and the energy consumption is further reduced.

Drawings

Fig. 1 is a schematic structural diagram provided in embodiment 1 of the present invention;

fig. 2 is a schematic structural diagram of the material pushing device in fig. 1 according to embodiment 1 of the present invention;

fig. 3 is a plan view of a cam provided in embodiment 1 of the present invention;

FIG. 4 is a schematic structural diagram of the feeding device in FIG. 1 according to embodiment 1 of the present invention;

fig. 5 is a bottom view of the ring gear provided in embodiment 1 of the present invention;

FIG. 6 is an enlarged view of the point A in FIG. 4 according to embodiment 1 of the present invention;

FIG. 7 is a schematic view of the flattening apparatus and printing apparatus of FIG. 1, in accordance with embodiment 1 of the present invention;

FIG. 8 is a partial top view of FIG. 7 provided in accordance with embodiment 1 of the present invention;

fig. 9 is a schematic structural diagram of the material pushing device in fig. 1 according to embodiment 2 of the present invention.

In the figure: the material pushing device 100, the feeding device 200, the flattening device 300, the printing apparatus 400, the supporting plate 500, the cam 101, the auxiliary rod 102, the jacking block 103, the jacking rod 104, the pulling block 105, the traction block 106, the supporting leg 107, the transmission assembly II 108, the secondary belt pulley 109, the transmission assembly I110, the servo motor 111, the hammer gear I113, the hammer gear II 114, the supporting plate II 115, the vertical shaft I116, the hammer gear III 117, the hammer gear IV 118, the supporting plate I119, the horizontal shaft 120, the hammer gear V121, the hammer gear VI 122, the vertical shaft II 123, the main belt pulley 124, the supporting platform I125, the tension spring 126, the belt 127, the screw rod 201, the baffle 202, the sleeve 203, the sleeve rod 204, the corrugated board 205, the ring gear 206, the driving wheel 207, the stepping motor 208, the lower inclined rod 209, the supporting block 210, the driving nut 211, the rotating shaft 212, the upper inclined rod 213, the mounting block 214, the supporting plate II 215, the supporting, The device comprises a limiting plate 301, a shaft rod 302, a conveyor belt 303, a flattening wheel 304, a hammer-shaped gear seven 305, a hammer-shaped gear eight 306, a vertical shaft three 307, a fixing plate 308, a hammer-shaped gear ten 309 and a hammer-shaped gear nine 310.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

Example 1:

referring to fig. 1 to 8 in the specification, the portable printing device for corrugated paper boxes in this embodiment includes a material pushing device 100, a material supplying device 200, and a pressing device 300, the material supplying device 200 is disposed on the right side of the material pushing device 100, the pressing device 300 is disposed on the right side of the material supplying device 200, the printing device 400 is disposed on the right side of the pressing device 300, and bottoms of the material pushing device 100, the material supplying device 200, and the pressing device 300 are all fixedly mounted on a supporting plate 500;

the material pushing device 100 comprises a first transmission component 110, a servo motor 111 and a first support platform 125, wherein the first transmission component 110 comprises a first hammer-shaped gear 113, a second hammer-shaped gear 114, a second support plate 115, a first vertical shaft 116, a third hammer-shaped gear 117, a fourth hammer-shaped gear 118, a first support plate 119, a transverse shaft 120, a fifth hammer-shaped gear 121, a sixth hammer-shaped gear 122 and a second vertical shaft 123, the first hammer-shaped gear 113 is meshed with the second hammer-shaped gear 114, the inner wall of the second hammer-shaped gear 114 is sleeved with the first vertical shaft 116, one end, far away from the second hammer-shaped gear 114, of the first vertical shaft 116 is sleeved with the third hammer-shaped gear 117, the third hammer-shaped gear 117 is meshed with the fourth hammer-shaped gear 118, the inner wall of the fourth hammer-shaped gear 118 is sleeved with the transverse shaft 120, the outer wall of the left end of the transverse shaft 120 is sleeved with the fifth hammer-shaped gear 121, the fifth hammer-shaped gear 121 is meshed, the outer wall of one end, far away from the hammer gear six 122, of the second vertical shaft 123 is sleeved with the cam 101, the top of the first support table 125 is fixedly provided with the traction block 106, the inner wall of the traction block 106 is inserted with the ejector rod 104, one end of the ejector rod 104 is fixedly connected with the pulling block 105, one end of the pulling block 105 is fixedly connected with the tension spring 126, and one end of the tension spring 126 is fixedly connected with the auxiliary rod 102; the servo motor 111 is arranged at 130HMB300B-3010003000, and the servo motor 111 is used for driving the cam 101 to rotate, driving the object stage 217 to ascend and driving the flattening wheel 304 to rotate; the first transmission assembly 110 is used for driving the cam 101 to rotate by utilizing the rotation of the screw rod 201; the cam 101 is used for pushing the top block 103 intermittently, so that the corrugated paper boards 205 on the object stage 217 are pushed onto the conveyor belt 302 intermittently and continuously;

the feeding device 200 comprises an object stage 217, the object stage 217 is provided with corrugated boards 205, the bottom of the object stage 217 is fixedly provided with a ring gear 206, the bottom of the object stage 217 is fixedly connected with a rotating shaft 212 through a bearing, one end of the rotating shaft 212 far away from the object stage 217 is fixedly connected with a second supporting plate 215 through a bearing, the ring gear 206 is engaged with a driving wheel 207, the outer wall of the driving wheel 207 is sleeved with the output end of a stepping motor 208, the bottom of the second support plate 215 is fixedly connected with the support block 210 through a bolt, the bottom of the support block 210 is movably connected with an upper inclined rod 213 through a mounting block 214, one end of the upper inclined rod 213 far away from the supporting block 210 is fixedly connected with a driving nut 211 through the mounting block 214, the bottom of the driving nut 211 is fixedly connected with a lower inclined rod 209 through the mounting block 214, and the inner wall of the driving nut 211 is in threaded connection with a screw rod 201; the stepping motor 208 is arranged as 20BYG250-33, and the stepping motor 208 is used for driving the object stage 217 to select so as to facilitate the placement of the corrugated boards 205 stacked together on the object stage 217;

the flattening device 300 comprises a limiting plate 301, the inner wall of the limiting plate 301 is fixedly connected with a shaft rod 302 through a bearing, the outer wall of the shaft rod 302 is sleeved with a flattening wheel 304, a conveying belt 303 is arranged below the flattening wheel 304, the outer wall of the shaft rod 302 is sleeved with a hammer-shaped gear seven 305, the hammer-shaped gear seven 305 is meshed and connected with a hammer-shaped gear eight 306, the inner wall of the hammer-shaped gear eight 306 is sleeved with a vertical shaft three 307, the outer wall of one end, far away from the hammer-shaped gear eight 306, of the vertical shaft three 307 is sleeved with a hammer-shaped gear nine 310, and the hammer-shaped gear nine 310 is meshed and.

Further, the inner wall of the first hammer gear 113 is sleeved with the screw rod 201, and the output end of the servo motor 111 is fixedly connected with the screw rod 201.

Furthermore, the outer wall of the second vertical shaft 123 is fixedly connected with a first support platform 125 through a bearing, a first support plate 119 is fixedly installed at the bottom of the first support platform 125, and one end, far away from the first support platform 125, of the first support plate 119 is fixedly connected with the horizontal shaft 120 through a bearing.

Further, the stepping motor 208 is fixedly mounted on the second support plate 215, and the mounting block 214 at the bottom end of the lower inclined rod 209 is fixedly mounted on the support plate 500.

Further, the outer wall of the screw rod 201 is fixedly connected with a supporting column 216 through a bearing, and the bottom of the supporting column 216 is fixedly installed on the supporting plate 500.

Further, the inner wall of the ten hammer-shaped gears 309 is sleeved with the screw rod 201, the inner wall of the first hammer-shaped gear 113 is sleeved with the screw rod 201, and the outer wall of the third vertical shaft 307 is fixedly connected with the fixing plate 308 through a bearing.

Furthermore, one end of the object stage 217 is fixedly connected with a sleeve 203, the inner wall of the sleeve 203 is inserted with a sleeve rod 204, and the outer surface of the sleeve 203 is fixedly connected with a baffle 202.

Furthermore, the bottom of the first support platform 125 is fixedly provided with a support leg 107, the outer wall of the first vertical shaft 116 is fixedly connected with a second support plate 115 through a bearing, and one end of the second support plate 115 is fixedly arranged on the first support platform 125.

Furthermore, the shape and the structure of the first hammer gear 113, the second hammer gear 114, the third hammer gear 117, the fourth hammer gear 118, the fifth hammer gear 121 and the sixth hammer gear 122 are the same, and the bottom end of the auxiliary rod 102 is fixedly connected with the first support platform 125.

The implementation scenario is specifically as follows: when the invention is used, the stepping motor 208 is started, the output end of the stepping motor 208 drives the driving wheel 207 to rotate, the driving wheel 207 drives the ring gear 206 to rotate, the ring gear 206 drives the object stage 217 to rotate ninety degrees, the laminated corrugated paper board 205 is placed on the object stage 217, the reversing stepping motor 208 is reversed to restore the object stage 217, the servo motor 111 and the printing equipment 400 are started, the servo motor 111 drives the screw rod 201 to rotate, the screw rod 201 drives the hammer gear II 114 and the vertical shaft I116 to rotate through the hammer gear I113, the vertical shaft I116 drives the hammer gear IV 118 to rotate through the hammer gear III 117, the hammer gear IV 118 drives the hammer gear V121 to rotate through the transverse shaft 120, the hammer gear V121 drives the hammer gear VI 122 to rotate, the hammer gear VI 122 drives the cam 101 to rotate through the vertical shaft II 123, and the outermost end of the cam 101 contacts the top block 103, pushing the top block 103 to the right, pushing the top corrugated board 205 on the object stage 217 out by the top block 103 through the top rod 104 and dropping on the conveyor belt 303 of the flattening device 300, and then restoring the top block 103 and the top rod 104 to the original positions under the action of the tension spring 126; the screw rod 201 drives the hammer-shaped gear nine 310 to rotate through the hammer-shaped gear ten 309, the hammer-shaped gear nine 310 drives the hammer-shaped gear eight 306 to rotate through the vertical shaft three 307, the hammer-shaped gear eight 306 drives the hammer-shaped gear seven 305 to rotate, the shaft lever 302 and the flattening wheel 304 are further driven to rotate, the corrugated board 205 on the conveying belt 303 is flattened through the flattening wheel 304, and then the corrugated board is input into the printing equipment 400 to be printed; meanwhile, the screw rod 201 drives the driving nut 211 to move, and as the driving nut 211 is movably connected with the lower inclined rod 209 and the upper inclined rod 213 through the mounting block 214, the object stage 217 is jacked up to jack the uppermost corrugated board 205 to be at the same height as the top rod 104; the cam 101 then continues to rotate to push the uppermost corrugated cardboard sheet 205 on the stage 217 onto the conveyor belt 303, and the stage 217 continues to be lifted.

Example 2:

referring to the attached fig. 9 of the specification, the difference from the embodiment 1 is: the screw rod 201 is in transmission connection with a second transmission assembly 108, the second transmission assembly 108 comprises a main belt pulley 124, a belt 127, a secondary belt pulley 109, a first support plate 119, a transverse shaft 120, a fifth hammer-shaped gear 121, a sixth hammer-shaped gear 122 and a second vertical shaft 123, the main belt pulley 124 is in transmission connection with the secondary belt pulley 109 through the belt 127, and the inner wall of the secondary belt pulley 109 is sleeved with the transverse shaft 120; the second transmission assembly 108 is used for driving the cam 101 to rotate by utilizing the rotation of the screw rod 201;

the implementation scenario is specifically as follows:

when the invention is used, the stepping motor 208 is started, the output end of the stepping motor 208 drives the driving wheel 207 to rotate, the driving wheel 207 drives the ring gear 206 to rotate, the ring gear 206 drives the object stage 217 to rotate ninety degrees, the laminated corrugated paper board 205 is placed on the object stage 217, the reversing stepping motor 208 is reversed, the object stage 217 is restored to the original position, the servo motor 111 and the printing equipment 400 are started, the servo motor 111 drives the screw rod 201 to rotate, the screw rod 201 drives the belt 127 to transmit through the main belt pulley 124, the belt 127 drives the driven belt pulley 109 to rotate, the driven belt pulley 109 drives the transverse shaft 120 to rotate, the transverse shaft 120 drives the hammer gear five 121 to rotate, the hammer gear five 121 drives the hammer gear six 122 to rotate, the hammer gear six 122 drives the cam 101 to rotate through the vertical shaft two 123, when the outermost end of the cam 101 contacts the top block 103, the top block 103 pushes the top corrugated paper board 205 on the object stage 217 out through the top rod 104 and pushes the top layer of the conveying Then, under the action of the tension spring 126, the ejector block 103 and the ejector rod 104 are restored to the original positions; the screw rod 201 drives the hammer-shaped gear nine 310 to rotate through the hammer-shaped gear ten 309, the hammer-shaped gear nine 310 drives the hammer-shaped gear eight 306 to rotate through the vertical shaft three 307, the hammer-shaped gear eight 306 drives the hammer-shaped gear seven 305 to rotate, the shaft lever 302 and the flattening wheel 304 are further driven to rotate, the corrugated board 205 on the conveying belt 303 is flattened through the flattening wheel 304, and then the corrugated board is input into the printing equipment 400 to be printed; meanwhile, the screw rod 201 drives the driving nut 211 to move, and as the driving nut 211 is movably connected with the lower inclined rod 209 and the upper inclined rod 213 through the mounting block 214, the object stage 217 is jacked up to jack the uppermost corrugated board 205 to be at the same height as the top rod 104; the cam 101 then continues to rotate to push the uppermost corrugated cardboard sheet 205 on the stage 217 onto the conveyor belt 303, and the stage 217 continues to be lifted.

The above description is only a preferred embodiment of the present invention, and any person skilled in the art may modify the present invention or modify it into an equivalent technical solution by using the technical solution described above. Therefore, any simple modifications or equivalent substitutions made in accordance with the technical solution of the present invention are within the scope of the claims of the present invention.

Claims (10)

1. The utility model provides a corrugated box is with convenient type lithography apparatus, includes blevile of push (100), feedway (200), flattening device (300), blevile of push (100) right side is equipped with feedway (200), feedway (200) right side is equipped with flattening device (300), flattening device (300) right side is equipped with lithography apparatus (400), its characterized in that: the bottoms of the pushing device (100), the feeding device (200) and the flattening device (300) are fixedly arranged on the supporting plate (500);

the material pushing device (100) comprises a first transmission component (110), a servo motor (111) and a first support platform (125), wherein the first transmission component (110) comprises a first hammer-shaped gear (113), a second hammer-shaped gear (114), a second support plate (115), a first vertical shaft (116), a third hammer-shaped gear (117), a fourth hammer-shaped gear (118), a first support plate (119), a transverse shaft (120), a fifth hammer-shaped gear (121), a sixth hammer-shaped gear (122) and a second vertical shaft (123), the first hammer-shaped gear (113) is meshed with the second hammer-shaped gear (114), the inner wall of the second hammer-shaped gear (114) is sleeved with the first vertical shaft (116), one end, far away from the second hammer-shaped gear (114), of the first vertical shaft (116) is sleeved with the third hammer-shaped gear (117), the third hammer-shaped gear (117) is meshed with the fourth hammer-shaped gear (118), and the inner wall of the fourth hammer-shaped gear (118) is, the outer wall of the left end of the transverse shaft (120) is sleeved with a hammer-shaped gear five (121), the hammer-shaped gear five (121) is in meshed connection with a hammer-shaped gear six (122), the inner wall of the hammer-shaped gear six (122) is sleeved with a vertical shaft two (123), the outer wall of one end, away from the hammer-shaped gear six (122), of the vertical shaft two (123) is sleeved with a cam (101), the top of the support table one (125) is fixedly provided with a traction block (106), the inner wall of the traction block (106) is inserted with a push rod (104), one end of the push rod (104) is fixedly connected with a pull block (105), one end of the pull block (105) is fixedly connected with a tension spring (126), and one end of the tension;

the feeding device (200) comprises an object stage (217), a corrugated board (205) is arranged on the object stage (217), a ring gear (206) is fixedly installed at the bottom of the object stage (217), the bottom of the object stage (217) is fixedly connected with a rotating shaft (212) through a bearing, one end, far away from the object stage (217), of the rotating shaft (212) is fixedly connected with a second supporting plate (215) through a bearing, the ring gear (206) is meshed with a driving wheel (207), the outer wall of the driving wheel (207) is sleeved with an output end of a stepping motor (208), the bottom of the second supporting plate (215) is fixedly connected with a supporting block (210) through a bolt, the bottom of the supporting block (210) is movably connected with an upper inclined rod (213) through a mounting block (214), one end, far away from the supporting block (210), of the upper inclined rod (213) is fixedly connected, the bottom of the driving nut (211) is fixedly connected with a lower inclined rod (209) through the mounting block (214), and the inner wall of the driving nut (211) is in threaded connection with a screw rod (201);

flattening device (300) includes limiting plate (301), limiting plate (301) inner wall passes through bearing fixed connection axostylus axostyle (302), axostylus axostyle (302) outer wall cup joints flattening wheel (304), flattening wheel (304) below is equipped with conveyer belt (303), axostylus axostyle (302) outer wall cup joints hammer-shaped gear seven (305), hammer-shaped gear eight (306) meshing connection hammer-shaped gear is seven (305), hammer-shaped gear eight (306) inner wall cup joints vertical axis three (307), vertical axis three (307) are kept away from hammer-shaped gear nine (310) are cup jointed to the one end outer wall of hammer-shaped gear eight (306), hammer-shaped gear ten (309) are connected in hammer-shaped gear nine (310) meshing.

2. The portable printing device for corrugated containers as claimed in claim 1, wherein: the inner wall of the hammer-shaped gear I (113) is sleeved with the screw rod (201), and the output end of the servo motor (111) is fixedly connected with the screw rod (201).

3. The portable printing device for corrugated containers as claimed in claim 1, wherein: the outer wall of the vertical shaft II (123) is fixedly connected with a supporting platform I (125) through a bearing, a supporting plate I (119) is fixedly installed at the bottom of the supporting platform I (125), and one end, far away from the supporting platform I (125), of the supporting plate I (119) is fixedly connected with the horizontal shaft (120) through a bearing.

4. The portable printing device for corrugated containers as claimed in claim 1, wherein: the stepping motor (208) is fixedly arranged on the second support plate (215), and the mounting block (214) at the bottom end of the lower inclined rod (209) is fixedly arranged on the support plate (500).

5. The portable printing device for corrugated containers as claimed in claim 1, wherein: the outer wall of the screw rod (201) is fixedly connected with a supporting column (216) through a bearing, and the bottom of the supporting column (216) is fixedly installed on the supporting plate (500).

6. The portable printing device for corrugated containers as claimed in claim 1, wherein: the inner wall of the first hammer gear (113) is sleeved with the screw rod (201), and the outer wall of the third vertical shaft (307) is fixedly connected with the fixing plate (308) through a bearing.

7. The portable printing device for corrugated containers as claimed in claim 1, wherein: one end of the object stage (217) is fixedly connected with a sleeve (203), a sleeve rod (204) is inserted into the inner wall of the sleeve (203), and a baffle (202) is fixedly connected to the outer surface of the sleeve (203).

8. The portable printing device for corrugated containers as claimed in claim 1, wherein: the supporting legs (107) are fixedly mounted at the bottoms of the first supporting tables (125), the outer walls of the first vertical shafts (116) are fixedly connected with second supporting plates (115) through bearings, and one ends of the second supporting plates (115) are fixedly mounted on the first supporting tables (125).

9. The portable printing device for corrugated containers as claimed in claim 1, wherein: the shape and the structure of the first hammer-shaped gear (113), the second hammer-shaped gear (114), the third hammer-shaped gear (117), the fourth hammer-shaped gear (118), the fifth hammer-shaped gear (121) and the sixth hammer-shaped gear (122) are the same, and the bottom end of the auxiliary rod (102) is fixedly connected with the first support platform (125).

10. The portable printing device for corrugated containers as claimed in claim 1, wherein: the screw rod (201) is in transmission connection with a second transmission assembly (108), the second transmission assembly (108) comprises a main belt pulley (124), a belt (127), a secondary belt pulley (109), a first support plate (119), a transverse shaft (120), a fifth hammer-shaped gear (121), a sixth hammer-shaped gear (122) and a second vertical shaft (123), the main belt pulley (124) is in transmission connection with the secondary belt pulley (109) through the belt (127), and the inner wall of the secondary belt pulley (109) is sleeved with the transverse shaft (120).

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