CN212654703U - Biodegradable compression-resistant reinforcing piece for packaging carton - Google Patents

Abstract

The utility model relates to a biodegradable compression-resistant reinforcement for a packaging carton, which comprises a first compression-resistant reinforced side body and a second compression-resistant reinforced side body, wherein the first compression-resistant reinforced side body and the second compression-resistant reinforced side body are vertically connected into a whole at the longitudinal side edge; each compression-resistant reinforcing side body is provided with a top compression-resistant piece and a bottom compression-resistant piece integrally connected with the top compression-resistant piece through a supporting piece, and the end faces of the top compression-resistant piece and the bottom compression-resistant piece of the first compression-resistant reinforcing side body are respectively positioned on the same horizontal plane with the end faces of the top compression-resistant piece and the bottom compression-resistant piece of the second compression-resistant reinforcing side body. The top compression resisting parts and the bottom compression resisting parts which are positioned in the same compression resisting reinforcing side body are symmetrically distributed, the two top compression resisting parts and the two bottom compression resisting parts which are positioned in the adjacent compression resisting reinforcing side bodies are symmetrically distributed around the axis of the supporting member respectively, and each top compression resisting part and each bottom compression resisting part are of a triangular structure.

Description

Biodegradable compression-resistant reinforcing piece for packaging carton

Technical Field

The utility model belongs to the technical field of packaging material, concretely relates to packing is biodegradable resistance to compression reinforcement for carton.

Background

In recent years, with the development of online shopping and express logistics, the demand for packaging materials and packaging boxes made of the packaging materials is increasing.

However, most of the current packaging materials are corrugated cartons, and in order to improve the cushioning performance of the cartons, expanded plastics such as EPS, EPP and EPE are laid in the cartons to be used as cushioning packaging materials.

In addition, corrugated container board intensity is high, the rigidity is good, has better performances such as buffering simultaneously, the antivibration, and green, and have better environment friendly performance, and recoverable recycles, but corrugated container's defect lies in that the corrugated container that has adorned article stacks when the stock is piled up the pile up the pressure by four right angle supports, consequently, in case the pressure exceeds the tolerance limit that the right angle supported, packing carton is very easily collapsed and is out of shape and make the incasement article lose the support guard action of box, on the other hand, adopt corrugated container as the packing box of article, also very easily be out of shape, collapse in logistics circulation or transportation, the box has been damaged or brokenly completely even when addressee's receipts goods, totally lost the due effect of packing box. It can be seen that the strength of the corrugated box needs to be enhanced.

In order to enhance the impact resistance of the corrugated paper packaging box, the prior art with the publication number of CN205589641U discloses a green environment-friendly high-strength corrugated paper packaging box, which comprises a box body made of a corrugated composite paper board, wherein the corrugated composite paper board is composed of surface paper, lining paper and a corrugated layer arranged between the surface paper and the lining paper, the corrugated layer comprises corrugated paper and degradable plastic foaming layers arranged on two surfaces of the corrugated paper, and the lining paper, the surface paper, the corrugated paper and the degradable plastic foaming layers are all degradable materials, so that the environment is protected; the degradable plastic foaming layers are arranged on the two surfaces of the corrugated paper, the plastic foaming layers enable the number of internal gaps to be increased sharply and the volumes of the gaps to be increased through a foaming process, and the plastic foaming layers have elasticity and can absorb and disperse external impact force through bending to achieve a buffering effect, so that the impact resistance of the packing box can be enhanced; all be provided with the enhancement strip on each arris in the box, the intensity of each corner of reinforcing packing box that can be better reduces the damage probability of each corner of packing box.

SUMMERY OF THE UTILITY MODEL

In order to overcome the technical problem who exists among the prior art, the utility model provides a packing is biodegradable resistance to compression reinforcement for carton to realize through following technical scheme: the biodegradable compression-resistant reinforcing piece for the packaging carton is characterized in that:

the biodegradable compression-resistant reinforcing piece comprises a first compression-resistant reinforcing side body and a second compression-resistant reinforcing side body, wherein the first compression-resistant reinforcing side body and the second compression-resistant reinforcing side body are vertically connected into a whole at the longitudinal side edge;

each compression-resistant reinforcing side body is provided with a top compression-resistant piece and a bottom compression-resistant piece integrally connected with the top compression-resistant piece through a supporting piece, and the end faces of the top compression-resistant piece and the bottom compression-resistant piece of the first compression-resistant reinforcing side body are respectively positioned on the same horizontal plane with the end faces of the top compression-resistant piece and the bottom compression-resistant piece of the second compression-resistant reinforcing side body.

Preferably, the top compression member and the bottom compression member in the same compression-resistant reinforcing side body are symmetrically distributed, and the two top compression members and the two bottom compression members in the adjacent compression-resistant reinforcing side bodies are symmetrically distributed about the support axis respectively.

Preferably, each of the top compression resistant member and the bottom compression resistant member is a triangular structure.

Preferably, a hollow structure is arranged in the triangular structure.

Preferably, the hollowed-out structure is a hollow triangle.

Preferably, the integral connection adopts a connecting rib for foldable movable connection.

Preferably, the first compression-resistant reinforced side body and the second compression-resistant reinforced side body are made of biodegradable plastics.

Preferably, the biodegradable plastic is a plant fiber reinforced polylactic acid biodegradable composite material.

The utility model discloses the beneficial effect who realizes does: the utility model relates to a resistance to compression reinforcement of packing carton sets up resistance to compression reinforcement and obtains resistance to compression packing carton through the side junction at the box, has effectively improved the box and has piled up the compressive capacity of putting things in good order, commodity circulation or transportation at the stock, keeps the integrality of box and to the protective properties of content. Meanwhile, the compression-resistant reinforcing piece is made of degradable materials, and is green and environment-friendly.

Drawings

Fig. 1 is a schematic view of a crush resistant packing carton.

Fig. 2 is a schematic cross-sectional structure of the tank body.

Fig. 3 is a schematic structural view of a biodegradable compression reinforcement.

FIG. 4 is a schematic diagram of a hollow structure.

Fig. 5 is a schematic view of the movable connection of the connecting ribs.

Detailed Description

In order to make the technical problem, technical solution and advantageous effects to be solved by the present invention clearer and more obvious, the following description of the present invention with reference to the accompanying drawings and embodiments is provided for further details. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

In order to make the technical problem, technical solution and advantageous effects to be solved by the present invention clearer and more obvious, the following description of the present invention with reference to the accompanying drawings and embodiments is provided for further details. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

Referring to fig. 1-5, the anti-compression packing carton of the present invention comprises a carton body 1, wherein the carton body 1 comprises a square box body formed by four side bodies which are sequentially vertically connected end to end, and the structure thereof is characterized in that:

the four connecting end corners of the box body are respectively provided with a biodegradable compression-resistant reinforcing part 2. Specifically, biodegradable compression-resistant reinforcements 2A, biodegradable compression-resistant reinforcements 2B, biodegradable compression-resistant reinforcements 2C and biodegradable compression-resistant reinforcements 2D are respectively arranged at the four connecting end corners.

Each biodegradable compression reinforcement comprises a first compression-reinforcing side body 101, a second compression-reinforcing side body 102, the first compression-reinforcing side body 101 and the second compression-reinforcing side body 102 being vertically connected at longitudinal side edges to form a whole. Wherein:

the first compression-resistant reinforced side body 101 is provided with a first top compression-resistant member 21 and a first bottom compression-resistant member 23 integrally connected to the first top compression-resistant member 21 by a first support member 25, and the second compression-resistant reinforced side body 102 is provided with a second top compression-resistant member 22 and a second bottom compression-resistant member 24 integrally connected to the second top compression-resistant member 22 by a second support member (not shown).

Specifically, the end surfaces of the first top compression resisting element 21 and the second top compression resisting element 22 are located on the same horizontal plane as the top end surface of the box body, and meanwhile, the end surfaces of the first bottom compression resisting element 23 and the second bottom compression resisting element 24 are located on the same horizontal plane as the bottom end surface of the box body.

Specifically, for each of the biodegradable compression reinforcement members, the top compression member and the bottom compression member within the same compression reinforcement side body are symmetrically distributed, such as: the first top compression resistant elements 21 and the first bottom compression resistant elements 23 in the first compression-resistant reinforced side body 101 are symmetrically distributed, and the second top compression resistant elements 22 and the second bottom compression resistant elements 24 in the second compression-resistant reinforced side body 102 are symmetrically distributed.

Specifically, the two top compression-resistant pieces and the two bottom compression-resistant pieces in the adjacent compression-resistant reinforcing side bodies are respectively and symmetrically distributed about the support axis, such as: the first top compression springs 21 in the first compression-resistant reinforcing side body 101 and the second top compression springs 22 in the second compression-resistant reinforcing side body 102 are symmetrically distributed about the support axis. Similarly, the first bottom compression element 23 in the first compression-resistant reinforcing side body 101 and the second bottom compression element 24 in the second compression-resistant reinforcing side body 102 are symmetrically distributed about the support axis.

In a specific embodiment, each of the top compression resisting element and the bottom compression resisting element is a triangular structure, and specifically, a hollow structure is arranged in the triangular structure, such as: the first top compression resisting part 21 and the first bottom compression resisting part 23 which are located in the first compression resisting reinforcing side body 101 are both triangular structures, a hollow structure 201 is arranged in the first top compression resisting part 21, and a hollow structure 202 is arranged in the first bottom compression resisting part 23. Preferably, the hollow structures 201 and 202 are hollow triangles.

In a specific embodiment, the integral connection is foldable and movable by using the connecting rib 203.

When the biodegradable compression-resistant reinforcing piece is used, the vertical connection between the two compression-resistant reinforcing side bodies is arranged at the right-angle connection part of the two adjacent side bodies, namely: the perpendicular connection between the first pressure-resistant reinforced side body 101 and the second pressure-resistant reinforced side body 102 is arranged at the right-angle connection position of two adjacent side surface bodies, the first pressure-resistant reinforced side body 101 and the second pressure-resistant reinforced side body 102 are respectively implanted into the two adjacent side surface bodies, and the top end surface and the bottom end surface of each pressure-resistant reinforced side body are respectively flush with the two end surfaces of the side surface bodies, so that the pressure resistance of the box body is enhanced.

The compression-resistant reinforcing piece is arranged at the connecting position of the side face of the box body, so that the compression resistance of the box body in the processes of stock stacking, logistics circulation or transportation is improved, and the integrity of the box body and the protection performance of the box body on contents are kept. Meanwhile, the compression-resistant reinforcing piece is made of degradable materials, and is green and environment-friendly.

In order to enhance the environment-friendly performance of the packaging material, the first compression-resistant reinforced side body and the second compression-resistant reinforced side body are made of biodegradable plastics. Preferably, the biodegradable plastic is a plant fiber reinforced polylactic acid biodegradable composite material. In order to enhance the environment-friendly performance of the packaging material, the first compression-resistant reinforced side body and the second compression-resistant reinforced side body are made of biodegradable plastics. Preferably, the biodegradable plastic is a plant fiber reinforced polylactic acid biodegradable composite material. The plant fiber reinforced polylactic acid biodegradable composite material is an existing material, wherein the plant fiber comprises bagasse fiber, coconut fiber, tea fiber and the like, and the existing material can be obtained by a person skilled in the art according to the prior art. Such as: the bagasse/polylactic acid composite material can be obtained by technicians in the field according to the prior art provided by the great masses and the like (the influence of a bagasse modification method on the structure and the performance of the bagasse/polylactic acid composite material [ J ]. the school report of composite materials, 2018, 35 (9): 2369-2378), the bagasse/polylactic acid composite material can also be obtained according to the prior art provided by the von-Yanghua and the like (the preparation of PLA/bagasse composite material and the research on the performance thereof [ J ] (plastic industry, 2010, 38 (1): 25-28), and the paper fiber reinforced PLA/PBAT degradable composite material can also be obtained according to the prior art provided by the slow flushing (the research on the performance of office waste paper fiber reinforced PLA/PBAT degradable composite material [ D ], the university of Western Enhan chemical industry).

While the foregoing description shows and describes the preferred embodiments of the present invention, it is to be understood that the invention is not limited to the forms disclosed herein, but is not intended to be exhaustive or to exclude other embodiments and may be used in various other combinations, modifications, and environments and is capable of changes within the scope of the inventive concept as expressed herein, commensurate with the above teachings, or the skill or knowledge of the relevant art. But that modifications and variations may be effected by those skilled in the art without departing from the spirit and scope of the invention, which is to be limited only by the claims appended hereto.

Claims (8)

1. The utility model provides a packing carton is with biodegradable resistance to compression reinforcement which characterized in that: the biodegradable compression-resistant reinforcing piece comprises a first compression-resistant reinforcing side body and a second compression-resistant reinforcing side body, wherein the first compression-resistant reinforcing side body and the second compression-resistant reinforcing side body are vertically connected into a whole at the longitudinal side edge; each compression-resistant reinforcing side body is provided with a top compression-resistant piece and a bottom compression-resistant piece integrally connected with the top compression-resistant piece through a supporting piece, and the end faces of the top compression-resistant piece and the bottom compression-resistant piece of the first compression-resistant reinforcing side body are respectively positioned on the same horizontal plane with the end faces of the top compression-resistant piece and the bottom compression-resistant piece of the second compression-resistant reinforcing side body.

2. The biodegradable crush-resistant reinforcement for packaging cartons as claimed in claim 1, wherein: the top compression resisting parts and the bottom compression resisting parts in the same compression resisting reinforcing side body are symmetrically distributed, and the two top compression resisting parts and the two bottom compression resisting parts in the adjacent compression resisting reinforcing side bodies are symmetrically distributed around the axis of the support respectively.

3. The biodegradable crush-resistant reinforcement for packaging cartons as claimed in claim 1, wherein: each top compression resisting piece and each bottom compression resisting piece are of triangular structures.

4. The biodegradable crush-resistant reinforcement for packaging cartons as claimed in claim 3, wherein: a hollow structure is arranged in the triangular structure.

5. The biodegradable crush-resistant reinforcement for packaging cartons as claimed in claim 4, wherein: the hollow structure is a hollow triangle.

6. The biodegradable crush-resistant reinforcement for packaging cartons as claimed in claim 1, wherein: the integrated connection adopts the connecting ribs to carry out foldable movable connection.

7. A biodegradable crush-resistant reinforcement for a packaging carton as claimed in any one of claims 1 to 5, wherein: the first compression-resistant reinforced side body and the second compression-resistant reinforced side body are made of biodegradable plastics.

8. The biodegradable crush-resistant reinforcement for packaging cartons as claimed in claim 7, wherein: the biodegradable plastic is a plant fiber reinforced polylactic acid biodegradable composite material.

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