CN220516926U - High-efficiency waste material treatment bottle cutting machine - Google Patents

Abstract

The utility model discloses a high-efficiency waste treatment bottle cutting machine, which comprises a working platform; the conveying belt of the conveying belt assembly is arranged opposite to the working platform, and a conveying channel is enclosed between the conveying belt and the working platform; the distance adjusting assembly is used for adjusting the distance between the transmission belt and the working platform; the cutting assembly comprises a first rotary cutter and a second rotary cutter which extend into the conveying channel, and the distance between the first rotary cutter and the second rotary cutter is adjustable; and the material blocking assembly is arranged adjacent to the cutting assembly, and when the first rotary cutter and the second rotary cutter respectively cut the bottle mouth and the bottle bottom of the bottle body, the material blocking assembly abuts against the bottle body to enable the bottle body to rotate. The material blocking assembly comprises a linear cylinder and a rotating wheel arranged at the power output end of the linear cylinder; the linear cylinder is used for driving the rotating wheel to extend into the conveying channel to abut against the outer wall of the bottle body or leave the conveying channel.

Description

High-efficiency waste material treatment bottle cutting machine

Technical Field

The application relates to the technical field of waste treatment devices, in particular to a high-efficiency waste treatment bottle cutting machine.

Background

Along with the increasing attention of people to food safety, the bottle body and the cup body made of plastic materials are adopted at present for catering purposes of users, the plastic made of the plastic materials is higher in cost than common plastic, and manufacturers are also promoted to collect unqualified products after the unqualified products are detected out through finished product output, so that secondary recycling is performed. Because the bottle mouth and the bottle bottom of the bottle body have low treatment and recovery values due to the structure and other reasons, the bottle body needs to be separated from the bottle body with uniform wall thickness and relatively regular shape, and then the bottle body is subjected to subsequent granulation treatment.

At present, the bottle mouth and the bottle bottom are separated from the bottle body by a device for cutting the bottle mouth and removing the bottle bottom waste material in a full-automatic linear rotation manner, such as the device disclosed in the application number CN202120347524.3, according to the full-text functional description, the bottle body is treated by separating the bottle mouth from the bottle body and separating the bottle bottom from the bottle body by two steps, and the two steps are completed by the two components.

Disclosure of Invention

The utility model mainly aims at the problems and provides a high-efficiency waste treatment bottle cutting machine, which aims at solving the technical problems in the background technology.

To achieve the above object, the present utility model provides a high-efficiency waste treatment bottle cutter comprising:

a working platform;

the conveying belt of the conveying belt assembly is arranged opposite to the working platform, and a conveying channel is enclosed between the conveying belt and the working platform;

the distance adjusting assembly is used for adjusting the distance between the transmission belt and the working platform;

the cutting assembly comprises a first rotary cutter and a second rotary cutter which extend into the conveying channel, and the distance between the first rotary cutter and the second rotary cutter is adjustable;

and the material blocking assembly is arranged adjacent to the cutting assembly, and when the first rotary cutter and the second rotary cutter cut the bottle mouth and the bottle bottom of the bottle body respectively, the material blocking assembly abuts against the bottle body to enable the bottle body to rotate.

Further, the material blocking assembly comprises a linear cylinder and a rotating wheel arranged at the power output end of the linear cylinder; the linear cylinder is used for driving the rotating wheel to extend into the conveying channel to abut against the outer wall of the bottle body or leave the conveying channel.

Further, the feeding guide hopper is connected with the feeding end of the conveying channel, and the feeding guide hopper is obliquely arranged from the feeding end of the feeding guide hopper to the feeding end of the conveying channel from high to low.

Further, the working platform is provided with a bar-shaped hole, and the feeding guide hopper comprises a first half hopper and a second half hopper which are symmetrically arranged; the first half bucket and the second half bucket are fixed through the strip-shaped holes in a penetrating mode through screws and are connected with the working platform.

Further, the interval adjusting assembly comprises a supporting vertical frame and an adjusting bolt group, and the conveying belt assembly is connected with the supporting vertical frame through the adjusting bolt group.

Further, the cutting assembly comprises a driving motor and a transmission shaft connected with the power output end of the driving motor; the first rotary cutter and the second rotary cutter are disc cutters and are in sliding sleeve connection with the outer wall of the transmission shaft, and the first rotary cutter and the second rotary cutter are respectively fixed with the transmission shaft through screws.

Further, the motor driving device comprises a transmission part, wherein the transmission shaft receives the driving force of the driving motor through the transmission part.

Further, a discharging through hole is formed in the position, corresponding to the first rotary cutter and the second rotary cutter, of the working platform, and a first receiving container is arranged at the lower end, corresponding to the discharging through hole.

Further, the discharge end of the conveying channel is connected with a discharge pipeline, and a second receiving container is arranged at the discharge end of the discharge pipeline.

Further, a sensor is arranged in the conveying channel and is used for collecting the passing information of the bottle body to be cut.

Compared with the prior art, the efficient waste treatment bottle cutting machine provided by the utility model can utilize one transmission device to convey the bottle body to be cut once, and can synchronously cut and separate the bottle bottom, the bottle mouth and the bottle body under the cooperation of the material blocking component; the bottle body cutter can be used for adapting to bottle bodies with different lengths under the characteristic that the interval between the first rotary cutter and the second rotary cutter is adjustable; can adjust transmission belt with under the characteristic of work platform interval at interval adjustment subassembly, can adapt to the bottle of cutting different external diameters, this whole commonality of machine is strong.

Drawings

FIG. 1 is a schematic diagram of a bottle cutter for efficient waste treatment.

Fig. 2 is a cross-sectional view of the efficient scrap handling bottle cutter of the present application.

FIG. 3 is a schematic view of a part of components of the efficient waste treatment bottle cutter.

Fig. 4 is an exploded view of the components of a portion of the efficient waste treatment bottle cutter of the present application.

Fig. 5 is a schematic view of a material blocking assembly of the efficient waste treatment bottle cutter.

Fig. 6 is a schematic structural view of a cutting assembly of the efficient waste treatment bottle cutter of the present application.

Fig. 7 is a schematic view of a part of the components of the efficient waste treatment bottle cutter.

Reference numerals shown in the drawings: 1. a working platform; 110. a bar-shaped hole; 120. a discharge through hole; 2. a conveyor belt assembly; 210. a conveyor belt; 3. a conveying channel; 4. a spacing adjustment assembly; 410. a supporting stand; 420. an adjusting bolt group; 430. a protection plate; 5. a cutting assembly; 510. a first rotary cutter; 520. a second rotary cutter; 530. a driving motor; 540. a transmission shaft; 550. a transmission member; 560. a connecting seat; 6. a material blocking component; 610. a straight line cylinder; 620. a rotating wheel; 7. a feed guide hopper; 710. a first half bucket; 720. a second half bucket; 8. a first receiving container; 9. a discharge pipe; 10. a second receiving container; 11. a sensor; 12. and a protective cover.

Detailed Description

Referring to fig. 1-7, the present embodiment provides a high efficiency waste treatment bottle cutter, comprising:

a working platform 1;

the conveyor belt assembly 2, a conveyor belt 210 of the conveyor belt assembly 2 is arranged opposite to the working platform 1, and a conveying channel 3 is enclosed between the conveyor belt 210 and the working platform 1;

a spacing adjustment assembly 4, wherein the spacing adjustment assembly 4 is used for adjusting the spacing between the transmission belt 210 and the working platform 1;

the cutting assembly 5 comprises a first rotary cutter 510 and a second rotary cutter 520 which extend into the conveying channel 3, and the space between the first rotary cutter 510 and the second rotary cutter 520 is adjustable;

the material blocking assembly 6 is arranged adjacent to the cutting assembly 5, and when the first rotary cutter 510 and the second rotary cutter 520 cut the bottle mouth and the bottle bottom of the bottle body respectively, the material blocking assembly 6 abuts against the bottle body to enable the bottle body to rotate.

Example 1

The bottle body which needs to be cut at the bottom and the bottle mouth is sent into the conveying channel 3 by manual or automatic equipment, the distance between the conveying end face of the conveying belt 210 of the conveying belt assembly 2 and the end face of the working platform 1 is adjusted in advance by the distance adjusting assembly 4, and the bottle body is in contact with the conveying end face of the conveying belt 210 and the end face of the working platform 1 correspondingly to the outer diameter of the bottle body which is processed and cut, so that the bottle body can be effectively transmitted, and the bottle body is conveyed to the positions of the first rotary cutter 510 and the second rotary cutter 520 in a rotary and non-deflection mode under the driving of the conveying belt 210 with consistent and stable speed at a large area and all positions as long as the bottle body enters into the conveying channel 3 in the direction of the right bottle mouth; the first rotary cutter 510 and the second rotary cutter 520 cut the contacted bottle bodies in a rotary mode, and as the distance between the first rotary cutter 510 and the second rotary cutter 520 is adjustable, the bottle bodies with different bottle bottoms and bottle mouth heights can be universally matched for cutting.

If the sizes of the first rotary cutter 510 and the second rotary cutter 520 are set to be large enough, the bottle body can be directly and completely separated from the bottle mouth and the bottle bottom through the first rotary cutter 510 and the second rotary cutter 520 under the conveying of the conveying belt 210, but the first rotary cutter 510 and the second rotary cutter 520 can easily extend into the conveying channel 3 too much to cut the conveying belt 210 to cause damage; because this bottle cutter has set up fender material subassembly 6, then can make first rotary cutter 510, second rotary cutter 520 only partly stretch into in the conveying channel 3, after contacting the bottle, only cut off the part that current contact was contacted, then under owing to keep off the effect of keeping off the body of material subassembly 6 to and under the continuous transmission drive of the transmission belt 210 of conveyer belt subassembly 2, the bottle whole only can be forced to take place the rotation in current position, after rotating a week, bottle and first rotary cutter 510, second rotary cutter 520 part contact department also wind a week, accomplish bottleneck, bottle bottom and separation of body naturally.

Therefore, the bottle cutting machine utilizes a transmission device to convey the bottle body to be cut once, and can cut and separate the bottle bottom, the bottle mouth and the bottle body synchronously under the cooperation of the material blocking component 6; and can be used for adapting to bottles with different lengths under the characteristic that the interval between the first rotary cutter 510 and the second rotary cutter 520 is adjustable; under the characteristic that the interval adjusting component 4 can adjust the transmission belt 210 with the interval of the working platform 1, the bottle of different external diameters can be cut in the adaptation, and the whole commonality of this machine is strong.

Example two

The bottle body which needs to be cut into the bottle bottom and the bottle mouth is sent into the conveying channel 3 by manual or automatic equipment, and the distance between the conveying end face of the conveying belt 210 of the conveying belt assembly 2 and the end face of the working platform 1 is adjusted by the distanceThe component 4 is adjusted in advance to correspond to the outer diameter of the bottle body to be processed and cut, so that the bottle body and the conveying end face of the conveying belt 210 and the working platform 1Are all abutted against end surfaces To touch toCan be effectively transmitted, so long as the bottle body enters the conveying channel 3 in the direction of the right bottle mouth, the bottle body is conveyed to the positions of the first rotary cutter 510 and the second rotary cutter 520 in a rotary and non-deflection mode under the drive of the conveying belt 210 with consistent and stable speed at all parts in a large area; the first rotary cutter 510 and the second rotary cutter 520 can be in an unpowered driving mode and are arranged in the conveying channel 3, the conveying belt 210 is used for driving the bottle body to continuously drive the bottle body to press the cutting edges of the first rotary cutter 510 and the second rotary cutter 520, the bottle body can not move continuously in the direction away from the feeding end of the conveying channel 3 under the action of the supporting bottle body of the blocking component 6, the whole bottle body can only be forced to rotate at the current position, and after the bottle body rotates for one circle, the contact part of the bottle body and the first rotary cutter 510 and the second rotary cutter 520 also winds for one circle, so that the bottle mouth, the bottle bottom and the bottle body are separated naturally.

Example III

The bottle body needing to be cut at the bottom of the bottle and the bottle mouth is sent into the conveying channel 3 by manual or automatic equipment, the end face distance between the conveying end face of the conveying belt 210 of the conveying belt assembly 2 and the end face of the working platform 1 is adjusted in advance through the distance adjusting assembly 4, the outer diameter of the bottle body corresponding to the processed and cut bottle body is enabled to be slightly larger than the outer diameter of the bottle body, after the bottle body enters the conveying channel 3, the bottle body is contacted with the working platform 1 below the conveying channel, a certain interval can be reserved between the conveying end face of the conveying belt 210 and the conveying end face of the conveying belt 210 on the conveying belt assembly, and the first rotary cutter 510 and the second rotary cutter 520 are spaced from the conveying end face of the conveying belt 210.

The first rotary cutter 510 and the second rotary cutter 520 are disc-shaped cutting pieces driven by active driving equipment, the bottle body enters the conveying channel 3 and moves to the positions of the first rotary cutter 510 and the second rotary cutter 520 to be cut into bottle bottoms and bottle mouths, in the cutting process, as a certain interval exists between the bottle body and the conveying end face of the conveying belt 210, the bottle body is driven by the rotating first rotary cutter 510 and the rotating second rotary cutter 520 to move upwards to be contacted with the conveying end face of the conveying belt 210, the bottle body rotates during the cutting, the part which is not cut moves to the first rotary cutter 510 and the second rotary cutter 520 under the driving of the conveying belt 210 to cut, and the rotating first rotary cutter 510 and the second rotary cutter 520 are driven to move upwards to be contacted with the conveying end face of the conveying belt 210 again, so that the bottle body rotates continuously until the bottle body rotates fully and the bottle bottoms and the bottle mouths are separated from the bottle body; in this period, the material blocking component 6 plays a role of supporting the bottle body, and the bottle body is prevented from being cut out into gaps corresponding to the outlines of the first rotary cutter 510 and the second rotary cutter 520, and then the bottle body is incompletely separated and flows to the subsequent stations through the first rotary cutter 510 and the second rotary cutter 520.

In the above embodiment, when the heights of the bottle mouth and the bottle bottom are consistent, the direction of the bottle mouth can be not adjusted when the bottle body to be cut is conveyed into the conveying channel 3, and the bottle is more convenient.

It should be noted that, according to the above principle, the power for rotating the bottle bodies in the conveying channel 3 is not from the material blocking assembly 6, but from the conveying belt 210 and/or the first and second rotary cutters 510 and 520.

Referring to fig. 2, 3 and 5, the material blocking assembly 6 includes a linear cylinder 610 and a runner 620 mounted at a power output end of the linear cylinder 610; the linear cylinder 610 is used for driving the runner 620 to extend into the conveying channel 3 to abut against the outer wall of the bottle body or leave the conveying channel 3.

When the runner 620 abuts against the bottle body, the bottle body is driven by the transmission belt 210 to rotate, the friction force is transmitted to the runner 620, and the runner 620 rotates, so that the rotation of the bottle body is not hindered.

When the bottle mouth, the bottle bottom and the bottle body are separated, the piston rod of the linear cylinder 610 drives the rotating wheel 620 to leave the conveying channel 3, the bottle body is not blocked any more, and the bottle body is conveyed to a subsequent station by the conveyor belt assembly 2.

Referring to fig. 1 and 2, the feeding guide hopper 7 is connected to the feeding end of the conveying channel 3, and the feeding guide hopper 7 is arranged from the feeding end to the feeding end of the conveying channel 3 from high to low.

The feeding guide hopper 7 can increase the distance from the feeding to the conveying channel 3, and because the conveying belt assembly 2 is automatic and mechanical, when the bottle body to be processed is operated and conveyed, the safety distance guarantee can be provided for the manpower. The feeding guide hopper 7 which is obliquely arranged from high to low can enable the bottle bodies to automatically roll down to the feeding end of the conveying channel 3 by means of gravity.

Referring to fig. 1 and 2, the working platform 1 is provided with a bar-shaped hole 110, and the feeding guide hopper 7 includes a first half hopper 710 and a second half hopper 720 which are symmetrically arranged; the first half bucket 710 and the second half bucket 720 are fixed to be connected with the working platform 1 through the strip-shaped holes 110.

The first half bucket 710 and the second half bucket 720 can move within the length range of the strip-shaped hole 110 to adapt to bottles with different lengths. The bottle body entering the conveying channel 3 can obtain guiding direction alignment. The feeding guide hopper 7 is arranged in a separated mode, so that the material consumption of the plate of the feeding guide hopper 7 can be saved, and the production cost is reduced.

Referring to fig. 1 and 7, the distance adjusting assembly 4 includes a supporting stand 410 and an adjusting bolt set 420, and the conveyor belt assembly 2 is connected to the supporting stand 410 through the adjusting bolt set 420.

The adjusting bolt group 420 includes both bolts and nuts, and by screwing the bolts, the height of the conveyor belt assembly 2 connected to one end of the adjusting bolt is adjusted, so that the conveyor belt assembly 2 is lifted on the working platform 1, instead of the conventional bottle body directly placed on the upper end face of the conveyor belt, the self-gravity of the bottle body is utilized to generate pressure friction force, and the pressure friction force can be conveyed by the conveyor belt. In some embodiments, the support stand 410 is mounted on the upper end surface of the work platform 1. Preferably, the outer wall of the supporting stand 410 is covered with a protection plate 430, so that the conveyor belt assembly 2 and the cutting assembly 5 are enclosed, and the safety is improved.

Referring to fig. 4 and 6, the cutting assembly 5 includes a driving motor 530 and a transmission shaft 540 connected to a power output end of the driving motor 530; the first rotary cutter 510 and the second rotary cutter 520 are disc cutters, and are slidably sleeved on the outer wall of the transmission shaft 540, and the first rotary cutter 510 and the second rotary cutter 520 are respectively fixed with the transmission shaft 540 through screws.

With this structure, the first rotary cutter 510 and the second rotary cutter 520 can be driven by the transmission shaft 540 simultaneously, and the bottle body can be cut.

In some embodiments, the transmission shaft 540 is penetrated by a connecting seat 560 with a bearing, the connecting seat 560 is connected with the lower end surface of the working platform 1, and the transmission shaft 540 is stably erected.

Referring to fig. 4 and 6, the transmission shaft 540 includes a transmission member 550, and the transmission shaft 540 receives the driving force of the driving motor 530 through the transmission member 550.

The transmission 550 is in some embodiments a driving pulley mounted on the power output of the drive motor 530, a driven pulley mounted on the drive shaft 540, and a belt engaging the driving pulley, the driven pulley. In some embodiments, the transmission 550 may also be in the form of a sprocket chain set.

Referring to fig. 1, 2 and 4, a discharge through hole 120 is formed in the working platform 1 corresponding to the first rotary cutter 510 and the second rotary cutter 520, and a first receiving container 8 is disposed corresponding to the lower end of the discharge through hole 120.

The first receiving container 8 is mainly used for receiving cut bottle mouth and bottle bottom waste.

Referring to fig. 2, a discharge pipe 9 is connected to the discharge end of the conveying channel 3, and a second receiving container 10 is disposed at the discharge end of the discharge pipe 9.

The second receiving container 10 receives the cut bottle body through the discharging pipeline 9.

Referring to fig. 7, a sensor 11 is disposed in the conveying channel 3, and the sensor 11 is used for collecting the passing information of the bottle to be cut.

In some embodiments, the sensor 11 may be any one of a pressure sensor and a light sensor, and is used for sensing and collecting information of a bottle to be cut, then transmitting the collected information to an upper computer for processing, and the upper computer further controls a pneumatic electromagnetic valve to enable the linear cylinder 610 to work, so that the rotating wheel 620 is pushed into the conveying channel 3 to support the bottle.

Preferably, the bottle cutting machine is provided with a protective cover 12 surrounding the first rotary cutter 510 and the second rotary cutter 520, so that the use safety of the device is improved.

Claims (10)

1. High-efficient waste material handles bottle cutting machine, its characterized in that includes:

a working platform;

the conveying belt of the conveying belt assembly is arranged opposite to the working platform, and a conveying channel is enclosed between the conveying belt and the working platform;

the distance adjusting assembly is used for adjusting the distance between the transmission belt and the working platform;

the cutting assembly comprises a first rotary cutter and a second rotary cutter which extend into the conveying channel, and the distance between the first rotary cutter and the second rotary cutter is adjustable;

and the material blocking assembly is arranged adjacent to the cutting assembly, and when the first rotary cutter and the second rotary cutter cut the bottle mouth and the bottle bottom of the bottle body respectively, the material blocking assembly abuts against the bottle body to enable the bottle body to rotate.

2. The efficient scrap handling bottle cutter of claim 1 wherein said baffle assembly includes a linear cylinder, a runner mounted to a power take off of said linear cylinder; the linear cylinder is used for driving the rotating wheel to extend into the conveying channel to abut against the outer wall of the bottle body or leave the conveying channel.

3. The efficient scrap handling bottle cutter of claim 1 including a feed guide scoop engaged with the feed end of the conveyor tunnel, the feed guide scoop being inclined from the feed end thereof to the feed end of the conveyor tunnel from high to low.

4. The efficient waste treatment bottle cutter as defined in claim 3, wherein the working platform is provided with a bar-shaped hole, and the feeding guide hopper comprises a first half hopper and a second half hopper which are symmetrically arranged; the first half bucket and the second half bucket are fixed through the strip-shaped holes in a penetrating mode through screws and are connected with the working platform.

5. The efficient scrap handling bottle cutter of claim 1 wherein the spacing adjustment assembly includes a support stand, an adjustment bolt set, the conveyor belt assembly being connected to the support stand by the adjustment bolt set.

6. The efficient waste treatment bottle cutter of claim 1, wherein the cutter assembly comprises a drive motor, a drive shaft connected to a power output of the drive motor; the first rotary cutter and the second rotary cutter are disc cutters and are in sliding sleeve connection with the outer wall of the transmission shaft, and the first rotary cutter and the second rotary cutter are respectively fixed with the transmission shaft through screws.

7. The efficient scrap handling bottle cutter of claim 6 including a transmission shaft receiving the drive force of the drive motor through the transmission member.

8. The efficient waste treatment bottle cutting machine according to claim 1, wherein a discharge through hole is formed in the working platform corresponding to the first rotary cutter and the second rotary cutter, and a first receiving container is arranged at the lower end of the discharge through hole.

9. The efficient waste treatment bottle cutter of claim 1, wherein the discharge end of the conveying channel is connected with a discharge pipeline, and the discharge end of the discharge pipeline is provided with a second receiving container.

10. The efficient waste treatment bottle cutter as claimed in claim 1, wherein a sensor is provided in the conveying passage, and the sensor is used for collecting passing information of the bottle body to be cut.