CN219789454U - Auxiliary box collecting device and box pasting machine - Google Patents

Abstract

The utility model discloses an auxiliary box collecting device and a box pasting machine, wherein the auxiliary box collecting device comprises a conveying component and a storage component, the conveying component comprises a first conveying mechanism, the first conveying mechanism comprises a first bracket, a first conveying part and a driving motor, the first conveying part is arranged on the first bracket, and the driving motor is in driving connection with the first conveying part; the storage component is arranged at the rear of the first conveying mechanism and is used for storing the packaging boxes; when the operation is carried out, the packing box is in a stacked moving state at the output end, and the conveying component can enable the packing box to be converted into an independent moving state from the stacked moving state. Above-mentioned supplementary box device of receiving is favorable to the electron count at the in-process of packing carton transition motion state, after the packing carton is piled up again, has created the condition for the automated case, and after adopting supplementary box device of receiving, can reduce the personnel's quantity demand to receiving the box process to reduce by a wide margin and receive the box cost. The box pasting machine comprises the auxiliary box collecting device.

Description

Auxiliary box collecting device and box pasting machine

Technical Field

The utility model relates to the technical field of packaging machinery, in particular to an auxiliary box collecting device and a box pasting machine.

Background

As shown in fig. 1, the box pasting machine comprises a pre-folding part, a main folding part and a folding part, when the box pasting machine works, the highest linear speed of the pre-folding part and the main folding part can work up to 300 meters/min, and after the glue is coated on the main folding part of the packaging box, the working speed of the folding part is suddenly reduced to 1-3 meters/min in order to dry and bond the glue of the box pasting, so that the folded time of the packaging box on the folding part is prolonged by reducing the linear speed. Because there is huge speed difference in the front and back ends of the box pasting machine, as shown in fig. 2, the packing box moves slowly in a state of being inclined and stacked at the output end of the folding part of the box pasting machine, and because the packing box is in an irregular stacking state, the packing box is difficult to take out the box and pack by an automatic means, and at present, the box can only be manually collected and packed by 3-4 people at the output end of the folding part, so that the box collecting cost is greatly increased.

Disclosure of Invention

Based on this, it is necessary to provide an auxiliary box-collecting device to solve the above-mentioned problems.

In addition, a box pasting machine is also provided.

An auxiliary box collecting device for connecting an output end of a folding part of a box pasting machine, comprising:

the conveying assembly comprises a first conveying mechanism, wherein the first conveying mechanism comprises a first bracket, a first conveying part and a driving motor, the first conveying part is arranged on the first bracket, and the driving motor is in driving connection with the first conveying part; and

the storage assembly is arranged behind the first conveying mechanism and used for storing the packaging boxes;

when the packaging box is operated, the packaging box is in a stacked moving state at the output end, and the conveying assembly can enable the packaging box to be changed into an independent moving state from the stacked moving state.

In one embodiment, the transfer assembly further comprises a second transfer mechanism disposed above the first transfer mechanism.

In one embodiment, the second conveying mechanism comprises a second bracket, a third bracket and a second conveying part, wherein the second bracket is fixedly connected with the first bracket, the third bracket is rotatably connected with the second bracket, and a gap is arranged between the second conveying part and the first conveying part.

In one embodiment, the second conveying part is a plurality of rollers.

In one embodiment, a counter is disposed on the third bracket.

In one embodiment, the storage assembly comprises a first storage mechanism, the first storage mechanism comprises a first storage groove and a first baffle plate, and the first baffle plate is arranged on one side, away from the first conveying mechanism, of the first storage groove.

In one embodiment, the first receiving mechanism further includes a first push plate, and the first push plate is disposed in the first receiving groove.

In one embodiment, the storage assembly further comprises a second storage mechanism, the second storage mechanism is arranged on one side, away from the first conveying mechanism, of the first storage mechanism, the second storage mechanism comprises a second storage groove and a second pushing plate, and the second pushing plate is arranged in the second storage groove.

In one embodiment, the first baffle is a flapper.

The box pasting machine comprises an auxiliary box collecting device, wherein the auxiliary box collecting device is any one of the auxiliary box collecting devices.

Above-mentioned supplementary box device of receiving, conveying assembly can make the packing carton change into independent motion from the motion of stacking, and after the packing carton got into and accomodates the subassembly, accomodate again and pile up, at the in-process that the packing carton changed motion, after the packing carton was piled up again, created the condition for the automation case, and after adopting supplementary box device of receiving, can reduce the demand to receiving box process personnel quantity to reduce receiving box cost by a wide margin.

Drawings

FIG. 1 is a schematic plan view of a prior art box pasting machine;

fig. 2 is a schematic view showing a stacked state of the package at an output end of a folding portion of the box pasting machine;

FIG. 3 is a schematic perspective view of an auxiliary box-receiving device according to an embodiment;

FIG. 4 is a schematic perspective view of the auxiliary box-receiving device shown in FIG. 3 when the box-receiving operation is performed;

FIG. 5 is a schematic perspective view of an auxiliary box-receiving device according to another embodiment;

FIG. 6 is a schematic perspective view of the auxiliary box-receiving device shown in FIG. 5 for box-receiving operation;

fig. 7 is a schematic perspective view of an auxiliary box-receiving device according to another embodiment;

FIG. 8 is a schematic perspective view of the auxiliary box-receiving device shown in FIG. 7 for box-receiving operation;

FIG. 9 is a schematic perspective view of an auxiliary box-receiving device according to another embodiment;

fig. 10 is a schematic perspective view of the auxiliary box-receiving device shown in fig. 9 when the box-receiving operation is performed.

Detailed Description

In order that the above objects, features and advantages of the utility model will be readily understood, a more particular description of the utility model will be rendered by reference to the appended drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present utility model. The utility model may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit or scope of the utility model, which is therefore not limited to the specific embodiments disclosed below.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" or "in communication" with another element, it can be directly connected to the other element or intervening elements may also be present. The terms "upper," "lower," "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

The auxiliary box-receiving device 10 will be described in further detail below, mainly with reference to the drawings and the specific embodiments.

Referring to fig. 3 and 4, an auxiliary box-receiving device 10 in an embodiment includes a conveying assembly 11 and a receiving assembly 12.

The conveying assembly 11 includes a first conveying mechanism 111, and the first conveying mechanism 111 includes a first bracket 1111, a first conveying portion 1112, and a driving motor 1113.

Specifically, the first bracket 1111 is configured to carry the first conveying portion 1112 and the driving motor 1113, and in this embodiment, the first bracket 1111 is in a table-type structure, and the first bracket 1111 is made of an aluminum alloy.

The first transfer part 1112 is provided on the first holder 1111 and is configured to transfer the pack by rotating.

Specifically, the first conveying portion 1112 is flush with the output end of the folding portion 20, and this arrangement can reduce the resistance when the package box moves from the folding portion 20 to the first conveying portion 1112, and avoid further deformation of the stacked form of the package box when the package box encounters resistance, so as to facilitate continuous and stable conveying of the package box by the first conveying portion 1112.

Alternatively, the first conveying portion 1112 may be a conveyor belt or a conveying roller. In this embodiment, the first conveying section 1112 conveys the belt.

The driving motor 1113 is in driving connection with the first conveying part 1112, and is used for driving the first conveying part 1112 to rotate at a relatively high linear speed, so that after the packaging boxes enter the first conveying part 1112, the packaging boxes are converted from a low-speed stacked motion state to a high-speed independent motion state.

Specifically, the linear speed of the package at the output end of the folding portion 20 is about 1-3 m/min, the driving motor 1113 drives the first conveying portion 1112 to move at a linear speed of more than 30 m/min, and after the package contacts the first conveying portion 1112, the linear speed is instantaneously accelerated to more than 30 m/min under the action of the conveying assembly 11, so that the package is changed from the low-speed stacking state to the high-speed independent moving state.

It should be appreciated that the speed of movement of the first conveyor 1112 is related to the size of the packet, the linear speed of the packet at the output of the tuck portion 20, and in general, the smaller the packet, the higher the speed of conveyance of the first conveyor 1112; conversely, the larger the package, the lower the conveying speed of the first conveying portion 1112.

Preferably, the driving motor 1113 is electrically connected to the motor of the pre-folding portion of the box pasting machine, so that the linear speed of the first conveying portion 1112 is equal to the linear speed of the pre-folding portion of the box pasting machine, and at this time, the box pasting machine and the auxiliary box receiving device 10 are considered as a whole, so that the input and output of the packaging box are in a balanced state, thereby being beneficial to reducing the energy consumption of the box pasting machine.

Preferably, the driving motor 1113 is a variable frequency motor, which is easy to regulate speed, energy-saving and environment-friendly.

In another embodiment, referring to fig. 5 and 6, the conveying assembly 11 further includes a second conveying mechanism 112, the second conveying mechanism 112 is disposed above the first conveying mechanism 111, and the second conveying mechanism 112 includes a second bracket 1121, a third bracket 1122, and a second conveying portion 1123.

Specifically, the second bracket 1121 is fixedly connected to the first bracket 1111, one end of the third bracket 1122 is rotatably connected to the second bracket 1121, the other end is in contact with the first bracket 1111 through a pivot, the third bracket 1122 is provided with a second conveying portion 1123, the second conveying portion 1123 is rotatable, a gap is provided between the second conveying portion 1123 and the first conveying portion 1112, when the package box enters the gap, the lower surface of the package box contacts the first conveying portion 1112, the upper surface of the package box contacts the second conveying portion 1123, and the package box moves forward in the gap along with the rotation of the first conveying portion 1112 and the second conveying portion 1123. By providing the second conveying mechanism 112, on the one hand, the second conveying portion 1123 can apply a downward pressure to the packing box, thereby preventing the packing box from sliding on the first conveying portion 1112 due to the excessive weight, and further affecting the conveying speed and the conveying state; on the other hand, the second transfer part 1123 can reduce friction with the upper surface of the packing box by rotating, thereby preventing the printed surface of the packing box from being rubbed.

Alternatively, the second conveying portion 1123 is a conveyor belt or a plurality of rollers.

Preferably, the second transfer portion 1123 has a smooth or soft surface, which is provided to prevent the printed surface of the packing box from being rubbed, thereby ensuring that the quality of the product is not affected.

In the present embodiment, the second conveying part 1123 is a plurality of driven rollers, which can roll under the frictional force of the packing box, thereby preventing the surface of the packing box from being rubbed.

In another embodiment, the second conveying part 1123 is a plurality of active rollers having the same linear velocity as the first conveying part 1112 under the driving of the motor. This arrangement helps to further reduce the friction between the package and the transfer assembly 11, thereby preventing the surface of the package from being rubbed.

The storage unit 12 is provided behind the first conveying mechanism 111, and is configured to store the package.

Specifically, the storage assembly 12 includes a first storage mechanism 121, the first storage mechanism 121 includes a first storage groove 1211 and a first baffle 1212, the height of the first storage groove 1211 is lower than the height of the first conveying portion 1112, and the first baffle 1212 is disposed on a side of the first storage groove 1211 away from the first conveying mechanism 111. When the packing box leaves the first transfer part 1112, the packing box moves in a parabolic motion under the inertia effect and sequentially enters the upper part of the first storage groove 1211, collides with the first baffle 1212, and falls to the bottom of the first storage groove 1211 under the gravity effect, so that the packing box is re-stacked in the first storage groove 1211.

In another embodiment, referring to fig. 5 and 6, the first receiving mechanism 121 further includes a first push plate 1213, the first push plate 1213 is disposed in the first receiving slot 1211 and perpendicular to the first baffle 1212, and the first push plate 1213 is connected to the cylinder. When a predetermined number of packages are stacked in the first storage groove 1211, the first storage mechanism 121 is put in a leisure state, and at this time, the first push plate 1213 is pushed forward by the cylinder to push the stacked packages out of the first storage groove 1211, so that the packages enter the boxing process.

In another embodiment, referring to fig. 7 and 8, the storage assembly 12 further includes a second storage mechanism 122.

Specifically, the second storage mechanism 122 is disposed on a side of the first storage mechanism 121 away from the first conveying mechanism 111, the second storage mechanism 122 includes a second storage groove 1221 and a second baffle 1222, the height of the second storage groove 1221 is lower than that of the first conveying portion 1112, and the second baffle 1222 is disposed on a side of the second storage groove 1221 away from the first baffle 1212. When the packing boxes leave the first conveying portion 1112, the packing boxes pass over the first baffle 1212 to enter the second storage mechanism 122 in turn under the action of inertia, collide with the second baffle 1222, and fall to the bottom of the second storage groove 1221 under the action of gravity, so that the packing boxes are stacked again in the second storage groove 1221.

Preferably, the first shutter 1212 is a movable shutter, and the storage state of the first storage mechanism 121 or the second storage mechanism 122 can be controlled by changing the height or the shape of the first shutter 1212.

In the embodiment shown in fig. 7 and 8, the first shutter 1212 is a liftable shutter, and the storage state of the first storage mechanism 121 and the second storage mechanism 122 can be controlled by lifting the first shutter 1212.

Specifically, when the first baffle 1212 is in the raised state, the height of the first baffle 1212 is higher, and the package cannot pass over the first baffle 1212 during the parabolic motion, so that the package falls into the first receiving slot 1211 under the blocking action of the first baffle 1212, thereby enabling the first receiving mechanism 121 to be in the receiving state and the second receiving mechanism 122 to be in the idle state. When the first baffle 1212 is in the falling state, the height of the first baffle 1212 is lower, and the package box passes through the first baffle 1212 to enter the second storage mechanism 122 in the parabolic motion process, collides with the second baffle 1222 and falls into the second storage groove 1221, so that the second storage mechanism 122 is in the box receiving state, and the first storage mechanism 121 is in the leisure state.

In the embodiment shown in fig. 9 and 10, the first shutter 1212 is a rotatable shutter, and the storage state of the first storage mechanism 121 and the second storage mechanism 122 can be controlled by rotating the first shutter 1212.

Specifically, first baffle 1212 includes baffle body and steering plate, and baffle body and steering plate all are E font design, and the E word opening of baffle body sets up, and the E word opening of steering plate sets up down, and the steering plate passes through the upside swing joint of steering spindle and baffle body. When the included angle between the steering plate and the baffle body is 0 degrees, the steering plate is embedded into the baffle body, at this time, the package box falls into the first storage groove 1211 under the action of the first baffle 1212, so that the first storage mechanism 121 is in a storage state, and the second storage mechanism 122 is in a leisure state. When the included angle between the steering plate and the baffle body is greater than ninety degrees, the steering plate is obliquely arranged above the first storage groove 1211, and the tail end of the steering plate is lower than the first conveying part 1112, so that the steering plate becomes a bridge connecting the second storage mechanism 122 and the conveying assembly 11, at this time, the second storage mechanism 122 is in a box-folding state, and the first storage mechanism 121 is in a leisure state.

Preferably, the steering plate is in a shape like a Chinese character 'Feng', when the included angle between the steering plate and the baffle body is 0 degrees, the lower side of the steering plate is embedded into the baffle body, and the upper side of the steering plate extends to the upper side of the baffle body, so that the height of the first baffle 1212 is increased, and when the first storage mechanism 121 is in a box-collecting state, the packing box is prevented from passing over the first baffle 1212 and entering the second storage mechanism 122, and errors are generated in the number of the collected boxes.

When the unfolding area of the package box is large, on one hand, the width of the first storage groove 1211 needs to be correspondingly large to accommodate the package box, and on the other hand, the linear speed of the box pasting machine and the auxiliary box receiving device 10 needs to be reduced to enable the production line to run smoothly, so that the difficulty of the package box entering the second storage mechanism 122 beyond the first baffle 1212 is increased. Therefore, by making the first baffle 1212 a rotatable baffle, when the angle between the deflector and the baffle body is greater than ninety degrees, the package box can smoothly enter the second storage mechanism 122 through the "bridge" formed by the deflector, so that the storage assembly 12 can smoothly store the package box.

Preferably, the width of the first and second receiving grooves 1211 and 1221 is adjustable so as to accommodate the receiving of different sized packages.

In the illustrated embodiment, the second receiving mechanism 122 further includes a second push plate 1223, the second push plate 1223 is disposed in the second receiving groove 1221 and perpendicular to the first baffle 1212, and the second push plate 1223 is connected to the cylinder. When a predetermined number of packages are stacked in the second storage groove 1221, the second storage mechanism 122 is in a leisure state, and at this time, the second push plate 1223 is pushed forward by the air cylinder to push the stacked packages out of the second storage groove 1221, so that the packages enter the boxing process.

In another embodiment, referring to fig. 5 and 6, a counter 13 is disposed on the third bracket 1122, the counter 13 is electrically connected to the first baffle 1212, and when the counter 13 collects a predetermined number of packages passing through the first conveying portion 1112, the controller controls the first baffle 1212 to change the height or state of the first receiving mechanism 121 and the second receiving mechanism 122.

Above-mentioned supplementary box-packed putting 10 of receiving, conveying component 11 can make the packing carton change into independent motion from the motion that stacks, and after the packing carton got into storage component 12, accomodate again and stack, in the in-process that the packing carton changed motion, be favorable to the electron count, after the packing carton was stacked again, created the condition for the automated case, and after adopting supplementary box-packed putting 10, can reduce the personnel's quantity demand to receiving the box to reduce by a wide margin and receive the box cost.

The output end of the folding part 20 is connected with the auxiliary box collecting device 10, and the auxiliary box collecting device 10 can be any auxiliary box collecting device 10.

The following are specific examples.

Example 1

Referring to fig. 3 and 4, the present embodiment provides an auxiliary box receiving device 10, which includes: a transfer assembly 11 and a receiving assembly 12.

The conveying assembly 11 includes a first conveying mechanism 111, the first conveying mechanism 111 includes a first bracket 1111, a first conveying portion 1112, and a driving motor 1113, the first conveying portion 1112 is disposed on the first bracket 1111, and the driving motor 1113 is in driving connection with the first conveying portion 1112. The storage assembly 12 is disposed behind the first conveying mechanism 111, the storage assembly 12 includes a first storage groove 1211 and a first baffle 1212, and the first baffle 1212 is disposed on a side of the first storage groove 1211 away from the conveying assembly 11. In this embodiment, the first conveying portion 1112 is a conveying belt. In operation, the package is in a stacked motion state at the output end of the folding portion 20, and the conveying assembly 11 can enable the package to be converted from the stacked motion state to an independent motion state.

Above-mentioned supplementary box-packed putting 10 of receiving, conveying component 11 can make the packing carton change into independent motion from the motion that stacks, and after the packing carton got into storage component 12, accomodate again and stack, in the in-process that the packing carton changed motion, be favorable to the electron count, after the packing carton was stacked again, created the condition for the automated case, and after adopting supplementary box-packed putting 10, can reduce the personnel's quantity demand to receiving the box to reduce by a wide margin and receive the box cost.

Example 2

Referring to fig. 5 and 6, the auxiliary box-collecting device 10 provided in this embodiment is similar to the auxiliary box-collecting device 10 provided in embodiment 1, except that: (1) The conveying assembly 11 further includes a second conveying mechanism 112, where the second conveying mechanism 112 is disposed above the first conveying portion 1112, specifically, the second conveying mechanism 112 includes a second support 1121, a third support 1122, and a second conveying portion 1123, the second support 1121 is fixedly connected to the first support 1111, the third support 1122 is rotatably connected to the second support 1121, and a gap is disposed between the second conveying portion 1123 and the first conveying portion 1112. (2) The first housing mechanism 121 further includes a first push plate 1213, and the first push plate 1213 is connected to the cylinder. In the present embodiment, the second conveying unit 1123 is a plurality of auxiliary wheels.

In the auxiliary box collecting device 10, the second conveying mechanism 112 is provided, so that the second conveying portion 1123 can apply a downward pressure to the package box, thereby preventing the package box from sliding on the first conveying portion 1112 due to the light weight, and further affecting the conveying speed and the conveying state. By providing the first push plate 1213, when the number of packages in the first storage groove 1211 reaches a predetermined number, the packages can be pushed out of the first storage groove 1211, and the packages can be brought into the boxing process.

Example 3

Referring to fig. 7 and 8, the auxiliary box-collecting device 10 provided in this embodiment is similar to the auxiliary box-collecting device 10 provided in embodiment 2, except that: (1) a counter 13 is provided on the second support 1121; (2) The accommodating assembly 12 comprises a first accommodating mechanism 121 and a second accommodating mechanism 122, the second accommodating mechanism 122 comprises a second accommodating groove 1221, a second baffle 1222 and a second push plate 1223, and the second push plate 1223 is connected with the air cylinder; (3) the first shutter 1212 is a liftable shutter.

The auxiliary box collecting device 10 can accurately count the packing boxes stored in the storage assembly 12 by arranging the counter 13; by providing the first storage mechanism 121 and the second storage mechanism 122 at the same time, the storage state of the first storage mechanism 121 and the second storage mechanism 122 can be controlled by adjusting the height of the first shutter 1212.

Example 4

Referring to fig. 9 to 10, the auxiliary box-collecting device 10 provided in this embodiment is similar to the auxiliary box-collecting device 10 provided in embodiment 3, except that: the first baffle 1212 is a rotatable baffle, and specifically, the first baffle 1212 includes a baffle body and a turning plate, the baffle body and the turning plate are both in an E-shaped design, an E-shaped opening of the baffle body is upward arranged, an E-shaped opening of the turning plate is downward arranged, and the turning plate is movably connected with the upper side of the baffle body through a turning shaft

The auxiliary box-receiving device 10 is provided with the first baffle 1212 as a rotatable baffle when the unfolding area of the package box is large, and the package box can be smoothly received in the second receiving mechanism 122 through the bridge formed by the steering plate when the included angle between the steering plate and the baffle body is larger than ninety degrees, so that the receiving assembly 12 can successfully receive the package box.

The above examples illustrate only a few embodiments of the utility model, which are described in detail and are not to be construed as limiting the scope of the utility model. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model. Accordingly, the scope of protection of the present utility model is to be determined by the appended claims.

Claims (10)

1. An auxiliary box collecting device for connecting the output end of a folding part of a box pasting machine, which is characterized by comprising:

the conveying assembly comprises a first conveying mechanism, wherein the first conveying mechanism comprises a first bracket, a first conveying part and a driving motor, the first conveying part is arranged on the first bracket, and the driving motor is in driving connection with the first conveying part; and

the storage assembly is arranged behind the first conveying mechanism and used for storing the packaging boxes;

when the packaging box is operated, the packaging box is in a stacked moving state at the output end, and the conveying assembly can enable the packaging box to be changed into an independent moving state from the stacked moving state.

2. The auxiliary box-collecting device according to claim 1, wherein the conveying assembly further comprises a second conveying mechanism, and the second conveying mechanism is arranged above the first conveying mechanism.

3. The auxiliary box collecting device according to claim 2, wherein the second conveying mechanism comprises a second bracket, a third bracket and a second conveying part, the second bracket is fixedly connected with the first bracket, the third bracket is rotatably connected with the second bracket, and a gap is arranged between the second conveying part and the first conveying part.

4. A device according to claim 3, wherein the second conveying part is a plurality of rollers.

5. The auxiliary box-collecting device according to claim 4, wherein a counter is arranged on the third bracket.

6. The auxiliary box-receiving device according to any one of claims 1 to 5, wherein the receiving assembly comprises a first receiving mechanism, the first receiving mechanism comprises a first receiving groove and a first baffle, and the first baffle is disposed on a side of the first receiving groove away from the first conveying mechanism.

7. The auxiliary box collecting device according to claim 6, wherein the first collecting mechanism further comprises a first pushing plate, and the first pushing plate is arranged in the first collecting groove.

8. The auxiliary box-collecting device according to claim 7, wherein the collecting assembly further comprises a second collecting mechanism, the second collecting mechanism is arranged on one side, away from the first conveying mechanism, of the first collecting mechanism, the second collecting mechanism comprises a second collecting groove and a second pushing plate, and the second pushing plate is arranged in the second collecting groove.

9. The auxiliary box-collecting device according to claim 8, wherein the first baffle is a movable baffle.

10. A box pasting machine, characterized by comprising an auxiliary box collecting device, wherein the auxiliary box collecting device is an auxiliary box collecting device according to any one of claims 1-9.