CN109095254B - Efficient uninterrupted stacking machine - Google Patents

Abstract

The invention discloses an uninterrupted efficient stacking machine which comprises a conveying assembly, a distributing assembly, an adjusting assembly and an additional mechanism, wherein the conveying assembly comprises a base, a first hydraulic rod, a transmission motor, a transmission roller, a transmission frame and a transmission belt, and the transmission frame is rotationally connected to the base; when using, rotate earlier according to the width of cardboard and be located on the horizontal pole hand round, the adjustment the baffle distance the distance of horizontal pole, then rotate and be located on the transfer line hand round, the adjustment is two interval between the side shield, will this moment the baffle with the side shield adjustment to the suitable position, current pile machine compares, the high-efficient pile machine of novel incessant formula can carry out incessant cardboard pile, is the suitable interval of cardboard adjustment simultaneously, prevents when piling up because the cardboard pile that the space of piling up too big or the undersize leads to is uneven, does not need artifical arrangement, and it is simple and convenient to use, has improved production efficiency.

Description

Efficient uninterrupted stacking machine

Technical Field

The invention belongs to the technical field of stacking machines, and particularly relates to an uninterrupted efficient stacking machine.

Background

The carton has the advantages of firmness, durability, easy processing, low manufacturing cost, cyclic utilization, environmental protection and the like, and is widely applied to the packaging and transportation industry. In the carton processing process, the printing is generally realized by a printing machine for printing the required cartons for showing the characteristics of transported products, trademarks of companies and the like, and in order to realize the production continuity, a stacking machine is arranged at the outlet of the printing machine, so that the cartons can be orderly stacked.

In order to improve the production efficiency, a full-automatic stacking machine is often adopted, for example, the invention patent with the publication number of CN104370143B discloses a full-automatic uninterrupted stacking machine, the scheme is that a carton board is conveyed by a conveying belt, the conveying belt in the conveying process can automatically ascend along with the stacking of products behind, when the conveying belt ascends to a preset height, a turnover plate below a chassis of a paper receiving part is automatically closed, the products are continuously conveyed, then a person pulls away the goods automatically stacked in front, a new bedplate is placed, after a lifting device automatically descends to the height of the new bedplate, a hydraulic system can automatically place the goods pre-stored on the turnover plate on the new bedplate in advance, a new round of stacking is started, and the automatic stacking effect is further realized.

However, in the process of stacking the paper boards, the uninterrupted stacking machine in the prior art has the disadvantages that the paper boards are easily stacked unevenly in the process of outputting the paper boards due to different specifications of the paper boards, subsequent arrangement is needed, the uninterrupted stacking machine is quite troublesome to use, a large amount of time and manpower are consumed, and the production efficiency is reduced.

Disclosure of Invention

The invention provides an uninterrupted efficient stacking machine, and aims to solve the problems that during the process of stacking paper boards, due to different specifications of the paper boards, the paper boards are easily stacked unevenly during the process of outputting the paper boards, subsequent arrangement is needed, the use is quite troublesome, a large amount of time and labor are consumed, and the production efficiency is reduced in the uninterrupted stacking machine in the prior art.

The invention is realized in such a way, the uninterrupted high-efficiency stacking machine comprises a conveying component, a distributing component, an adjusting component and an additional mechanism, wherein the conveying component comprises a base, a first hydraulic rod, a transmission motor, a transmission roller, a transmission frame and a transmission belt, the transmission frame is rotationally connected to the base, the transmission frame is positioned above the base, the upper end and the lower end of the first hydraulic rod are respectively rotationally connected to the transmission frame and the base, an output shaft of the transmission motor is in transmission connection with the transmission roller, the transmission roller is rotationally connected to the transmission frame, the transmission belt is sleeved on the outer surface of the transmission roller, the transmission motor is electrically connected with an external power supply, the distributing component comprises a second hydraulic rod, a cross rod, a portal frame, a movable support, a baffle, a left overturning motor, a left supporting plate, a right baffle and a right overturning motor, the portal frame is fixedly connected to the base, the portal frame is positioned on the left side of the transmission frame, the upper end and the lower end of the second hydraulic rod are respectively fixedly connected to the cross rod and the base, the cross rod is slidably connected to the portal frame, the movable support is slidably connected to the cross rod, the movable support is positioned on the left side of the cross rod, the baffle is fixedly connected to the movable support, the baffle is positioned below the movable support, the left overturning motor is fixedly connected to the baffle, the left overturning motor is positioned at the lower end of the baffle, an output shaft of the left overturning motor is in transmission connection with the left supporting plate, the right overturning motor is fixedly connected to the cross rod, the right overturning motor is positioned below the cross rod, an output shaft of the right overturning motor is in transmission connection with the right baffle, and the left overturning motor and the right overturning motor are both electrically connected with an external power supply of the right, the adjusting component comprises a hand wheel, a telescopic rack and an adjusting gear, the movable support is fixedly connected with the telescopic rack, the telescopic rack is positioned on the right side of the movable support, the hand wheel is in transmission connection with the adjusting gear, the adjusting gear is positioned in the transverse rod, the adjusting gear is in meshing connection with the telescopic rack, the additional mechanism comprises a transmission rod, a side baffle, a slider, an adjusting rack, a sliding rod, an adjusting gear, an adjusting box, a driving gear and a transmission gear, the two ends of the sliding rod are respectively and fixedly connected with the transverse rod and the adjusting box, the slider is in sliding connection with the sliding rod, the side baffle is fixedly connected with the slider, the side baffle is positioned below the slider, the adjusting rack is fixedly connected with the slider, the adjusting gear is in meshing connection with the adjusting rack, the adjusting gear, the transmission gear and the driving gear are all located inside the adjusting box, the transmission gear is in transmission connection with the adjusting gear, the driving gear is in meshing connection with the transmission gear, and the transmission rod is in transmission connection with the driving gear.

Preferably, the driving gear and the transmission gear are both bevel gears, and the driving gear and the transmission gear are perpendicular to each other.

Preferably, the number of hand-operated wheel is two, and one of them hand-operated wheel rotate connect in the horizontal pole, another one hand-operated wheel fixed connection in the transfer line.

Preferably, the number of the adjusting gears and the number of the telescopic racks are two, and the two groups of the telescopic racks and the adjusting gears are symmetrically distributed on two sides of the cross rod.

Preferably, the adjusting assembly further comprises a connecting rod, and the two adjusting gears are in transmission connection through the connecting rod.

preferably, the cross bar is T-shaped, the left supporting plate and the right baffle are located on the same horizontal plane, and the left supporting plate and the right baffle are equal in length.

Preferably, the number of the side baffles, the number of the sliding blocks and the number of the adjusting racks are two, and the two groups of the side baffles, the number of the sliding blocks and the number of the adjusting racks are symmetrically distributed on two sides of the adjusting box.

Preferably, the number of the sliding rods is four, and the sliding rods are symmetrically distributed on two sides of the adjusting box in pairs.

Preferably, the two adjusting racks are parallel to each other, and the two side baffles are parallel to each other.

Preferably, the right side of the transmission frame is further provided with a material guide plate, the material guide plate is fixedly connected to the base, and the material guide plate is parallel to the base.

Compared with the prior art, the invention has the beneficial effects that: the uninterrupted efficient stacking machine realizes orderly stacking of paperboards by arranging the side baffles, when the uninterrupted efficient stacking machine is used, the hand-operated wheels on the cross rods are rotated according to the widths of the paperboards to adjust the distance between the baffles and the cross rods, then the hand-operated wheels on the transmission rods are rotated to adjust the distance between the two side baffles, at the moment, the baffles and the side baffles are adjusted to proper positions, when the paperboards are stacked, the baffles are prevented from being too far away and too far away from the cross rods, front and back dislocation of the paperboards in the stacking process is avoided, meanwhile, the side baffles on the two sides are prevented from being dislocated in the stacking process, compared with the existing stacking machine, the novel uninterrupted efficient stacking machine can continuously stack the paperboards and adjust proper distance for the paperboards, the problem that when the stacking is carried out, due to the fact that the stacking space is too large or too small, the paperboards are not stacked neatly is solved, manual arrangement is not needed, the use is simple and convenient, and the production efficiency is improved.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the structural telescopic rack drive of the present invention;

FIG. 3 is a schematic view of a structural adjustment rack drive of the present invention;

FIG. 4 is a schematic view of the transmission of the structural transmission rod of the present invention;

In the figure: 1-conveying component, 11-base, 12-first hydraulic rod, 13-transmission motor, 14-transmission roller, 15-conveying frame, 16-transmission belt, 2-material-separating component, 21-second hydraulic rod, 22-cross rod, 23-portal frame, 24-movable support, 25-baffle, 26-left turning motor, 27-left supporting plate, 28-right baffle, 29-right turning motor, 3-adjusting component, 31-hand wheel, 32-telescopic rack, 33-adjusting gear, 34-connecting rod, 4-additional mechanism, 41-transmission rod, 42-side baffle, 43-sliding block, 44-adjusting rack, 45-sliding rod, 46-adjusting gear, 47-adjusting box, 48-driving gear, 49-drive gear.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

In the description of the present invention, it is to be understood that the terms "length", "width", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships illustrated in the drawings, and are used merely for convenience in describing the present invention and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present invention. Further, in the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

Referring to fig. 1-4, the present invention provides a technical solution: an uninterrupted high-efficiency stacking machine comprises a conveying assembly 1, a material distributing assembly 2, an adjusting assembly 3 and an additional mechanism 4, wherein the conveying assembly 1 comprises a base 11, a first hydraulic rod 12, a transmission motor 13, a transmission roller 14, a transmission frame 15 and a conveying belt 16, the transmission frame 15 is rotatably connected to the base 11, the transmission frame 15 is positioned above the base 11, the upper end and the lower end of the first hydraulic rod 12 are respectively rotatably connected to the transmission frame 15 and the base 11, an output shaft of the transmission motor 13 is rotatably connected to the transmission roller 14, the transmission roller 14 is rotatably connected to the transmission frame 15, the conveying belt 16 is sleeved on the outer surface of the transmission roller 14, the transmission motor 13 is electrically connected with an external power supply, the material distributing assembly 2 comprises a second hydraulic rod 21, a cross rod 22, a portal frame 23, a movable support 24, a baffle plate 25, a left overturning motor 26, a left supporting plate 27, a right baffle plate 28 and a right overturning motor 29, the portal, the portal frame 23 is positioned on the left side of the transmission frame 15, the upper end and the lower end of the second hydraulic rod 21 are respectively and fixedly connected to the cross rod 22 and the base 11, the cross rod 22 is slidably connected to the portal frame 23, the movable support 24 is slidably connected to the cross rod 22, the movable support 24 is positioned on the left side of the cross rod 22, the baffle 25 is fixedly connected to the movable support 24, the baffle 25 is positioned below the movable support 24, the left overturning motor 26 is fixedly connected to the baffle 25, the left overturning motor 26 is positioned at the lower end of the baffle 25, the output shaft of the left overturning motor 26 is in transmission connection with the left supporting plate 27, the right overturning motor 29 is fixedly connected to the cross rod 22, the right overturning motor 29 is positioned below the cross rod 22, the output shaft of the right overturning motor 29 is in transmission connection with the right baffle 28, the left overturning motor 26 and the right overturning motor 29 are both electrically connected with, the movable support 24 is fixedly connected to a telescopic rack 32, the telescopic rack 32 is positioned on the right side of the movable support 24, the hand-operated wheel 31 is in transmission connection with an adjusting gear 33, the adjusting gear 33 is positioned inside the cross rod 22, the adjusting gear 33 is in meshing connection with the telescopic rack 32, the additional mechanism 4 comprises a transmission rod 41, a side baffle 42, a sliding block 43, an adjusting rack 44, a sliding rod 45, an adjusting gear 46, an adjusting box 47, a driving gear 48 and a transmission gear 49, two ends of the sliding rod 45 are respectively and fixedly connected to the cross rod 22 and the adjusting box 47, the sliding block 43 is in sliding connection with the sliding rod 45, the side baffle 42 is fixedly connected to the sliding block 43, the side baffle 42 is positioned below the sliding block 43, the adjusting rack 44 is fixedly connected to the sliding block 43, the adjusting gear 46 is in meshing connection with the adjusting rack 44, the adjusting gear 46, the driving gear 48 is connected with the transmission gear 49 in a meshing mode, and the transmission rod 41 is connected with the driving gear 48 in a transmission mode.

In this embodiment, when rotating hand wheel 31 clockwise, hand wheel 31 drives adjusting gear 33 clockwise this moment, and adjusting gear 33 drives adjusting rack 32 and slides to the left side this moment, and when rotating hand wheel 31 counterclockwise, hand wheel 31 drives adjusting gear 33 anticlockwise this moment, and adjusting gear 33 drives adjusting rack 32 and slides to the right side this moment to adjust the interval of baffle 25 and horizontal pole 22.

In the embodiment, the side baffle plates 42 are arranged to stack the paper boards orderly, before the paper boards are used, the hand-operated wheel 31 positioned on the cross rod 22 is rotated according to the width of the paper boards, the hand-operated wheel 31 drives the adjusting gear 33 to rotate, when the hand-operated wheel 31 is rotated in the forward direction, the hand-operated wheel 31 drives the adjusting gear 33 to rotate clockwise, the adjusting gear 33 drives the adjusting rack 32 to slide to the left, when the hand-operated wheel 31 is rotated in the reverse direction, the hand-operated wheel 31 drives the adjusting gear 33 to rotate anticlockwise, the adjusting gear 33 drives the adjusting rack 32 to slide to the right, so that the distance between the baffle plate 25 and the cross rod 22 is adjusted, the phenomenon that the distance between the baffle plate 25 and the cross rod 22 is too large and too small is avoided, the paper boards are prevented from being staggered back and forth in the stacking process, then the hand-operated wheel 31 fixedly connected to the transmission rod 41 is rotated, at this time, the driving gear 48 drives the driving gear 49 to rotate, the driving gear 49 drives the adjusting gear 46 to rotate, when the adjusting gear 46 rotates, the adjusting gear 46 drives the two adjusting racks 44 to move, the two adjusting racks 44 drive the sliding block 43 to slide, thereby driving the two side guards 42 to move, further adjusting the distance between the two side guards 42, and avoiding front and back misalignment of the paper boards in the stacking process, when in use, the conveying belt 16 drives the paper boards to be transported to the right side, and the first hydraulic rod 12 in the conveying process can automatically rise along with the stacking of the paper boards, meanwhile, the second hydraulic rod 21 drives the cross rod 22 to rise simultaneously, when rising to a preset height, the left overturning motor 26 and the right overturning motor 29 drive the left supporting plate 27 and the right guard 28 to rotate, at this time, the left supporting plate 27 and the right guard 28 support the paper boards, and the worker removes the stacked paper boards below the left supporting plate 27 and the right, first hydraulic stem 12 and second hydraulic stem 21 descend simultaneously this moment, when descending the predetermined height, left side upset motor 26 and right side upset motor 29 drive left layer board 27 and right baffle 28 and rotate and open this moment, the cardboard piles up on the bottom plate again this moment, current stacking machine compares, neotype incessant high-efficient stacking machine, can carry out incessant cardboard pile, be the suitable interval of cardboard adjustment simultaneously, prevent when piling up because the cardboard pile that leads to is too big or the undersize in the space of piling up uneven, do not need artifical arrangement, it is simple and convenient to use, and the production efficiency is improved.

Further, the driving gear 48 and the transmission gear 49 are both bevel gears, and the driving gear 48 and the transmission gear 49 are perpendicular to each other.

in the present embodiment, transmission is performed by providing the driving gear 48 and the transmission gear 49, the driving gear 48 is rotated by the rotation of the transmission rod 41, the transmission gear 49 is rotated by the driving gear 48, and the adjustment gear 46 is rotated by the transmission gear 49.

furthermore, the number of the hand-operated wheels 31 is two, one hand-operated wheel 31 is rotatably connected to the cross rod 22, and the other hand-operated wheel 31 is fixedly connected to the transmission rod 41.

In this embodiment, the hand wheel 31 on the cross rod 22 is arranged to drive the adjusting gear 33 to rotate, when the hand wheel 31 on the cross rod 22 is rotated, at the moment, the hand wheel 31 drives the adjusting gear 33 to rotate, the hand wheel 31 fixedly connected to the transmission rod 41 is rotated, and the transmission rod 41 can be controlled to rotate.

Further, the number of the adjusting gears 33 and the number of the telescopic racks 32 are two, and the two groups of the telescopic racks 32 and the adjusting gears 33 are symmetrically distributed on two sides of the cross bar 22.

In this embodiment, when rotating hand wheel 31 clockwise, hand wheel 31 drives adjusting gear 33 clockwise this moment, and adjusting gear 33 drives adjusting rack 32 and slides to the left side this moment, and when rotating hand wheel 31 counterclockwise, hand wheel 31 drives adjusting gear 33 anticlockwise this moment, and adjusting gear 33 drives adjusting rack 32 and slides to the right side this moment to adjust the interval of baffle 25 and horizontal pole 22.

Further, the adjusting assembly 3 further comprises a connecting rod 34, and the two adjusting gears 33 are in transmission connection through the connecting rod 34.

In this embodiment, link through setting up connecting rod 34, when the interval of adjusting baffle 25 and horizontal pole 22, connect through connecting rod 34 transmission between two adjusting gear 33, when rotating hand wheel 31 in the same time, hand wheel 31 drives adjusting gear 33 clockwise this moment, adjusting gear 33 drives adjusting rack 32 and slides to the left side this moment, when rotating hand wheel 31 in the reverse time, hand wheel 31 drives adjusting gear 33 anticlockwise rotation this moment, adjusting gear 33 drives adjusting rack 32 and slides to the right side this moment, thereby the interval of adjusting baffle 25 and horizontal pole 22.

further, the cross bar 22 is arranged in a T shape, the left support plate 27 and the right baffle 28 are in the same horizontal plane, and the left support plate 27 and the right baffle 28 are equal in length.

In this embodiment, the cardboard is stacked by arranging the left supporting plate 27 and the right baffle plate 28, when in use, the conveyer belt 16 drives the cardboard to be transported to the right side, and the first hydraulic rod 12 in the conveying process can automatically rise along with the stacking of the cardboard, and the second hydraulic rod 21 drives the cross rod 22 to rise simultaneously, when the cardboard is raised to a preset height, the left turning motor 26 and the right turning motor 29 drive the left supporting plate 27 and the right baffle plate 28 to rotate, the cardboard is supported by the left supporting plate 27 and the right baffle plate 28, the stacked cardboard below the left supporting plate 27 and the right baffle plate 28 is moved away by a worker, the first hydraulic rod 12 and the second hydraulic rod 21 fall simultaneously, when the cardboard is lowered to the preset height, the left turning motor 26 and the right turning motor 29 drive the left supporting plate 27 and the right baffle plate 28 to rotate to be opened, and the cardboard is stacked on the bottom plate again.

Further, the number of the side baffles 42, the number of the sliding blocks 43 and the number of the adjusting racks 44 are two, and the two groups of the side baffles 42, the sliding blocks 43 and the adjusting racks 44 are symmetrically distributed on two sides of the adjusting box 47.

In the present embodiment, the distance between the two side guards 42 of the two side plates is adjusted by providing the adjusting rack 44, when the adjusting gear 46 rotates, the adjusting gear 46 drives the two adjusting racks 44 to move, and the two adjusting racks 44 drive the sliding block 43 to slide, so as to drive the two side guards 42 to move, thereby adjusting the distance between the two side guards 42.

Furthermore, the number of the slide rods 45 is four, and the slide rods 45 are symmetrically distributed on two sides of the adjusting box 47 in pairs.

In this embodiment, the slide bars 45 are arranged to support, the slide bars 45 are symmetrically distributed on two sides of the adjusting box 47 in pairs, two ends of each slide bar 45 are respectively and fixedly connected to the cross bar 22 and the adjusting box 47, and the four slide bars 45 support the adjusting box 47.

further, the two adjustment racks 44 are parallel to each other, and the two side guards 42 are parallel to each other.

In the present embodiment, the distance between the two side guards 42 of the two side plates is adjusted by providing the adjusting rack 44, when the adjusting gear 46 rotates, the adjusting gear 46 drives the two adjusting racks 44 to move, and the two adjusting racks 44 drive the sliding block 43 to slide, so as to drive the two side guards 42 to move, thereby adjusting the distance between the two side guards 42.

Further, the right side of the transmission frame 15 is further provided with a material guide plate, the material guide plate is fixedly connected to the base 11, and the material guide plate is parallel to the base 11.

In the present embodiment, the paper sheets are guided by the guide plate, and when the paper sheet feeding device is used, the processed paper sheets drop onto the guide plate from the discharge port of the printing machine, and the paper sheets slide to the conveyor belt 16 along the guide plate by the inertia, and then are conveyed.

The working principle and the using process of the invention are as follows: after the paper board stacking device is installed, before the paper board stacking device is used, the hand-operated wheel 31 positioned on the cross rod 22 is rotated according to the width of a paper board, the hand-operated wheel 31 drives the adjusting gear 33 to rotate, when the hand-operated wheel 31 is rotated in the forward direction, the hand-operated wheel 31 drives the adjusting gear 33 to rotate clockwise, the adjusting gear 33 drives the adjusting rack 32 to slide towards the left side, when the hand-operated wheel 31 is rotated in the reverse direction, the hand-operated wheel 31 drives the adjusting gear 33 to rotate anticlockwise, the adjusting gear 33 drives the adjusting rack 32 to slide towards the right side, so that the distance between the baffle 25 and the cross rod 22 is adjusted, the distance between the baffle 35 and the cross rod 22 is prevented from being too large or too small, front and back dislocation of the paper boards in the stacking process is avoided, then the hand-operated wheel 31 fixedly connected to the transmission rod 41 is rotated, the transmission rod 41 is controlled, the transmission gear 49 drives the adjusting gear 46 to rotate, when the adjusting gear 46 rotates, the adjusting gear 46 drives the two adjusting racks 44 to move, the two adjusting racks 44 drive the sliding block 43 to slide, thereby driving the two side baffles 42 to move, further adjusting the distance between the two side baffles 42, and avoiding front and back dislocation and misalignment of the paper boards in the stacking process, when in use, the conveying belt 16 drives the paper boards to be transported to the right side, the first hydraulic rod 12 in the conveying process can automatically rise along with the stacking of the paper boards, the second hydraulic rod 21 drives the cross rod 22 to rise simultaneously, when the paper boards rise to a preset height, the left turnover motor 26 and the right turnover motor 29 drive the left supporting plate 27 and the right baffle 28 to rotate, the paper boards are supported by the left supporting plate 27 and the right baffle 28, a worker removes the stacked paper boards below the left supporting plate 27 and the right baffle 28, and the first hydraulic rod 12 and the second hydraulic rod 21 simultaneously fall, when falling to predetermined height, left upset motor 26 and right upset motor 29 drive left layer board 27 and right baffle 28 this moment and rotate and open, the cardboard piles up on the bottom plate again this moment, current stacking machine compares, novel high-efficient stacking machine of incessant formula, can carry out incessant cardboard pile, be the suitable interval of cardboard adjustment simultaneously, prevent when piling up because the space of piling up is too big or the cardboard pile that the undersize leads to is uneven, do not need artifical arrangement, it is simple and convenient to use, and the production efficiency is improved.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. The utility model provides a high-efficient stacker of incessant formula, its characterized in that includes conveyor components (1), divides material subassembly (2), adjusting part (3) and additional mechanism (4), conveyor components (1) includes base (11), first hydraulic stem (12), drive motor (13), driving roller (14), driving frame (15) and conveyer (16), driving frame (15) rotate connect in base (11), driving frame (15) are located the top of base (11), the upper and lower both ends of first hydraulic stem (12) rotate respectively connect in driving frame (15) and base (11), the output shaft transmission of drive motor (13) connect in driving roller (14), driving roller (14) rotate connect in driving frame (15), conveyer (16) cover is located the surface of driving roller (14), the transmission motor (13) is electrically connected with an external power supply,

The material distribution assembly (2) comprises a second hydraulic rod (21), a cross rod (22), a portal frame (23), a movable support (24), a baffle (25), a left overturning motor (26), a left supporting plate (27), a right baffle (28) and a right overturning motor (29), the portal frame (23) is fixedly connected to the base (11), the portal frame (23) is located on the left side of the transmission frame (15), the upper end and the lower end of the second hydraulic rod (21) are respectively fixedly connected to the cross rod (22) and the base (11), the cross rod (22) is slidably connected to the portal frame (23), the movable support (24) is slidably connected to the cross rod (22), the movable support (24) is located on the left side of the cross rod (22), the baffle (25) is fixedly connected to the movable support (24), and the baffle (25) is located below the movable support (24), the left overturning motor (26) is fixedly connected to the baffle (25), the left overturning motor (26) is positioned at the lower end of the baffle (25), an output shaft of the left overturning motor (26) is connected to the left supporting plate (27) in a transmission manner, the right overturning motor (29) is fixedly connected to the cross rod (22), the right overturning motor (29) is positioned below the cross rod (22), an output shaft of the right overturning motor (29) is connected to the right baffle (28) in a transmission manner, and the left overturning motor (26) and the right overturning motor (29) are both electrically connected with an external power supply,

the adjusting component (3) comprises a hand-operated wheel (31), a telescopic rack (32) and an adjusting gear (33), the movable support (24) is fixedly connected with the telescopic rack (32), the telescopic rack (32) is positioned on the right side of the movable support (24), the hand-operated wheel (31) is in transmission connection with the adjusting gear (33), the adjusting gear (33) is positioned in the transverse rod (22), and the adjusting gear (33) is in meshing connection with the telescopic rack (32),

The additional mechanism (4) comprises a transmission rod (41), a side baffle (42), a sliding block (43), an adjusting rack (44), a sliding rod (45), an adjusting gear (46), an adjusting box (47), a driving gear (48) and a transmission gear (49), two ends of the sliding rod (45) are respectively and fixedly connected with the cross rod (22) and the adjusting box (47), the sliding block (43) is in sliding connection with the sliding rod (45), the side baffle (42) is fixedly connected with the sliding block (43), the side baffle (42) is positioned below the sliding block (43), the adjusting rack (44) is fixedly connected with the sliding block (43), the adjusting gear (46) is in meshing connection with the adjusting rack (44), and the adjusting gear (46), the transmission gear (49) and the driving gear (48) are all positioned inside the adjusting box (47), and a transmission gear (49) is in transmission connection with the adjusting gear (46), the driving gear (48) is in meshing connection with the transmission gear (49), and the transmission rod (41) is in transmission connection with the driving gear (48).

2. An uninterrupted high efficiency stacking machine according to claim 1, characterized in that the driving gear (48) and the transmission gear (49) are bevel gears, the driving gear (48) and the transmission gear (49) being perpendicular to each other.

3. The uninterrupted efficient stacking machine according to claim 1, wherein the number of the hand-operated wheels (31) is two, one hand-operated wheel (31) is rotatably connected to the cross rod (22), and the other hand-operated wheel (31) is fixedly connected to the transmission rod (41).

4. The efficient stacker of claim 1, wherein the number of said adjusting gears (33) and said telescopic racks (32) is two, and two sets of said telescopic racks (32) and said adjusting gears (33) are symmetrically distributed on both sides of said cross bar (22).

5. An uninterrupted efficient stacking machine according to claim 4, characterized in that the adjusting assembly (3) further comprises a connecting rod (34), and the two adjusting gears (33) are in transmission connection with each other through the connecting rod (34).

6. The efficient stacker of claim 1, wherein said cross bar (22) is configured as a T-shape, said left support plate (27) and said right baffle (28) are in the same horizontal plane, and said left support plate (27) and said right baffle (28) are equal in length.

7. The uninterrupted high-efficiency stacking machine according to claim 1, wherein the number of the side baffles (42), the sliding blocks (43) and the adjusting racks (44) is two, and two sets of the side baffles (42), the sliding blocks (43) and the adjusting racks (44) are symmetrically distributed on two sides of the adjusting box (47).

8. The uninterrupted high-efficiency stacking machine according to claim 1, wherein the number of the sliding rods (45) is four, and the sliding rods (45) are symmetrically distributed on two sides of the adjusting box (47) in pairs.

9. An efficient stacker according to claim 7 wherein said two adjustment racks (44) are parallel to each other and said two side guards (42) are parallel to each other.

10. The uninterrupted high-efficiency stacking machine according to claim 1, wherein a material guiding plate is further disposed on the right side of the transmission frame (15), and the material guiding plate is fixedly connected to the base (11), and the material guiding plate and the base (11) are parallel to each other.