CN107214781B

CN107214781B - Thin strip type solid wood composite integrated material

Info

Publication number: CN107214781B
Application number: CN201710411534.7A
Authority: CN
Inventors: 胡海
Original assignee: Guangxi Nanning Qiaosheng Wood Industry Co ltd
Current assignee: Guangxi Nanning Qiaosheng Wood Industry Co ltd
Priority date: 2017-05-31
Filing date: 2017-05-31
Publication date: 2023-06-02
Anticipated expiration: 2037-05-31
Also published as: CN107214781A

Abstract

A thin strip type solid wood composite integrated material is composed of a first composite board and a second composite board. In the invention, the combination of the square strips I and II is realized by directly adopting a thin strip (diameter is 2-3 CM) cylindrical wood mandrel to shave off very few four planes by a low-power simple four-side planing; the two-angle arc edge-falling small square strip is directly realized by adopting a four-angle arc edge-falling small square strip I or a four-angle arc edge-falling small square strip II which is longitudinally divided into two parts; the method has the advantages of simple processing, low energy consumption and high wood utilization rate. And the connecting surfaces of the first composite plate and the second composite plate are wavy cambered surfaces, so that the splicing and bonding areas of the two composite plates are larger and the bonding of the plates is firmer. After the first composite board and the second composite board are combined and spliced, the original splicing points of the first composite board and the second composite board are in dislocation adhesion, and the strength of the board is improved. The formed integrated board is correspondingly stable and firm, and overcomes the defects of the single wood.

Description

Thin strip type solid wood composite integrated material

Technical Field

The invention belongs to a novel artificial board, and particularly relates to a thin strip type solid wood composite integrated material.

Technical Field

The number of the cylinder-shaped wood mandrels of the thin strips (with the diameter of 2-3 CM) for producing the veneers and the plywood is huge, and how to reasonably and fully utilize the wood mandrels for reproducing the artificial boards is a difficult problem which needs to be solved by the artificial board production enterprises, and the problems of reducing waste, increasing income and increasing the supply quantity of the artificial boards are solved.

Because the technology of reusing the thin cylindrical wood core shaft for manufacturing the high-end solid wood laminated wood is still immature, the wood core shaft is still mostly burnt or processed into wood chips for producing fiber boards, and only a small part of the wood core shaft is applied to producing the sweeping handle and the relatively low-end solid wood laminated wood with low strength and low toughness.

At present, when the wood core shaft is applied to the preparation of solid wood integrated materials, the traditional four-side planing equipment is mainly adopted to plane the wood core shaft with thin strips in a cylindrical shape into square specifications and small square materials with four-side lines for production and utilization, so that the kinetic energy, the mechanical abrasion and the raw material consumption are extremely large, the processing cost is high, and the defects of unstable performance, high manufacturing cost and the like of finished products exist.

Meanwhile, when the wood core shaft is used as a raw material to produce the traditional solid wood integrated material, the finished product has the following technical defects: (1) because the natural tension deficiency defect exists in the wood core of the wood core shaft, the synthesized finished product is extremely easy to crack at the wood core position, so that the product is damaged and scrapped; (2) because the traditional plane splicing method is adopted, the bonding area between the wood square materials is limited, the bonding strength is weaker, and the finished product is easy to crack, scatter strips and the like.

In addition, when the thin cylindrical wood core shaft is used as a raw material and is produced by adopting a traditional integrated wood production process, the thin cylindrical wood core shaft is limited by the diameter of the wood core shaft, and only plates with limited thickness can be produced according to the diameter level of the wood core shaft, so that the requirements of the market on the thickness of various plates cannot be met.

Moreover, most of the constituent materials of the laminated wood are single wood. The single wood is easy to generate deformation, dry crack, distortion and other defects in the environment with large temperature and humidity changes. Which in turn affects the quality of the integrated material.

Disclosure of Invention

The invention aims to overcome the defects of the existing integrated board and provide a brand new thin strip type solid wood composite integrated board. The method specifically comprises the following steps: the laminated material consists of a first composite board (1) and a second composite board (2).

The invention is realized by the following technical scheme:

a thin strip type solid wood composite integrated material has the technical proposal that: the laminated material consists of a first composite board (1) and a second composite board (2).

The first composite board (1) is formed by processing a third composite board (3), the third composite board (3) is formed by a plurality of small square strips (4) with four corners and arc edges, wherein the small square strips (4) with four corners and arc edges are provided with four planes (5) and four corners and arc surfaces (6), and the small square strips (4) with four corners and arc edges are spliced to form the third composite board (3).

The composite board II (2) is formed by processing a composite board IV (7), and the composite board IV (7) consists of a plurality of square strips II (8) with four corners and two square strips 9 with two corners and circular edges; wherein, four corners circular arc edge small square strip two (8) are provided with four plane two (10), four corners cambered surface two (11), two corners circular arc edge small square strip (9) are provided with four plane three (12), two corners cambered surface (13), with above-mentioned a plurality of four corners circular arc edge small square strip two (8) and two corners circular arc edge small square strip (9) splice, during the concatenation, and two corners circular arc edge small square strip (9) are settled respectively in the left and right sides of a plurality of four corners circular arc edge small square strip two (8) assembly, form composite slab four (7) from this.

When the first composite board (1) and the second composite board (2) are combined into an integrated material, the first composite board (1) and the second composite board (2) are sequentially combined and spliced into a thin strip type solid wood composite integrated material according to the thickness requirement.

The invention has the following advantages:

1. the invention has novel structure composition, scientific and reasonable design.

2. In the invention, the four-corner arc edge-falling small square strips I (4) and the four-corner arc edge-falling small square strips II (9) which are combined to form the composite board I (1) and the composite board II (2) are realized by directly adopting a thin strip (diameter of 2-3 CM) cylindrical wood mandrel to plane out four planes of very few parts through low-power simple four-side planing; the two-angle arc edge-falling small square strip (9) is also realized by directly adopting a four-angle arc edge-falling small square strip I (4) or a four-angle arc edge-falling small square strip II (8) which is longitudinally divided into two parts; the method has the advantages of simple processing, low energy consumption and high wood utilization rate.

3. In the invention, the connecting surfaces of the first composite board (1) and the second composite board (2) are wavy cambered surfaces, so that the splicing and bonding areas of the two boards are larger and the bonding of the boards is firmer when the two boards are synthesized.

4. In the invention, after the first composite board (1) and the second composite board (2) are combined and spliced, the original splicing points of the first composite board (1) and the second composite board (2) are bonded in a staggered manner, and the strength of the board is improved.

5. In the invention, the formed thin-strip type solid wood composite integrated material not only has the physical characteristics of natural solid wood, but also overcomes the defects of the natural wood, and is scientific, reasonable, novel and unique. The method comprises the following steps: (1) The physical properties of natural wood are reserved, the air pipe fiber structure of the wood is not damaged, and the wood has a series of physical properties of the wood, such as indoor humidity adjustment, ultraviolet resistance and the like, of log materials; (2) The single wood has the defects of easy swelling, deformation, dry cracking, twisting and the like in the environment with large temperature and humidity changes, and particularly, the single wood has more outstanding performance than the single wood with larger size. The arc edge falling square strips prepared by the raw material fine strip cylindrical wood mandrel are tiny, the stress and the expansion coefficient of the square strips are correspondingly reduced, and when two plates are synthesized, the splicing and bonding area is larger, the anastomosis of the plates is firmer, and the formed integrated plate is correspondingly stable and firm, so that the defects of the single wood are overcome.

6. The invention fully utilizes the wood processing residues for secondary reproduction and cyclic utilization, and reduces environmental pollution caused by waste wood residues. Meanwhile, the market supply of the solid wood integrated materials is increased, the contradiction between supply and demand is eased, the timber harvest is reduced, and the income of enterprises is increased.

Drawings

The invention is further described below with reference to the accompanying drawings.

Fig. 1 is a schematic structural view of a strand-type solid wood composite laminate according to the present invention.

Fig. 2 is a schematic view of the structure of the composite board 1 of the present invention.

Fig. 3 is also a schematic view of the structure of the composite panel two (2) of the present invention.

Fig. 4 is a schematic view of the structure of a composite board three (3) in the present invention.

Fig. 5 is also a schematic view of the structure of the composite board three (3) of the present invention.

Fig. 6 is a schematic structural view of a square strip one (4) of a square arc edge of a composite board three (3) in the invention.

FIG. 7 is a schematic view of the structure of the square strip I (4) of the rectangular arc edge of the composite board III (3) of the invention.

Fig. 8 is a schematic view of the structure of a synthetic panel IV (7) in the present invention.

Fig. 9 is also a schematic view of the structure of the composite panel four (7) of the present invention.

Fig. 10 is a schematic structural view of a square strip II (8) of a square arc edge of a fourth synthetic plate (7) in the invention.

Fig. 11 is a schematic structural view of a square strip two (8) of the four-corner arc edge of the composite board four (7) in the invention.

Fig. 12 is a schematic view of the structure of the square strip of the two-corner arc falling edge of the composite board IV (7) in the invention.

Fig. 13 is a schematic view of the structure of the square strip of the rectangular plate four (7) with two-angle circular arc falling edges of the synthetic plate.

In fig. 1, 1 is a first composite board and 2 is a second composite board.

In fig. 2, 1 is a composite board one.

In fig. 3, 2 is a composite panel two.

In fig. 4, 3 is a composite plate three, and 4 is a square bar one with four corners and circular edges.

In fig. 5, 3 is a composite plate three, and 4 is a square bar one with four corners rounded off.

In fig. 6, 4 is a square bar of a square arc falling edge, 5 is a plane, and 6 is a square arc.

In fig. 7, 4 is a square bar of a square arc falling edge, 5 is a plane, and 6 is a square arc.

In fig. 8, 7 is a synthetic panel four, 8 is a square bar with four corners and edges falling in an arc shape, and 9 is a square bar with two corners and edges falling in an arc shape.

In fig. 9, 7 is a synthetic panel four, 8 is a square bar with four corners and edges, and 9 is a square bar with two corners and edges.

In fig. 10, 8 is a square bar of a square arc falling edge, 10 is a plane two, and 11 is a square arc surface two.

In fig. 11, 8 is a square bar of a square arc falling edge, 10 is a plane two, and 11 is a square arc surface two.

In fig. 12, 9 is a two-angle arc falling edge small square bar, 12 is a plane three, and 13 is a two-angle arc surface.

In fig. 13, 9 is a two-angle arc falling edge small square bar, 12 is a plane three, and 13 is a two-angle arc surface.

Detailed Description

The invention will now be described in detail with reference to the accompanying drawings and examples:

the invention is composed of a first synthetic plate (1) and a second synthetic plate (2).

Fig. 1 shows a schematic structure of the present invention. Wherein 1 is a first composite board and 2 is a second composite board.

Fig. 2, 4, 5, 6 and 7 are schematic structural views of the first (1), third (3) and other components of the composite panel of the present invention. The first composite board (1) is formed by processing a third composite board (3), the third composite board (3) is formed by a plurality of small square strips (4) with four corners and circular arc edges, wherein the small square strips (4) with four corners and circular arc edges are provided with four planes (5) and four corners and cambered surfaces (6), and the small square strips (4) with four corners and circular arc edges are spliced to form the third composite board (3).

Also shown in fig. 3, 8, 9, 10, 11, 12 and 13 are schematic structural views of the second (2), fourth (7) and other components of the present invention. The composite board II (2) is formed by processing a composite board IV (7), and the composite board IV (7) consists of a plurality of square strips II (8) with four corners and two square strips 9 with two corners and circular edges; wherein, four corners circular arc edge small square strip two (8) are provided with four plane two (10), four corners cambered surface two (11), two corners circular arc edge small square strip (9) are provided with four plane three (12), two corners cambered surface (13), with above-mentioned a plurality of four corners circular arc edge small square strip two (8) and two corners circular arc edge small square strip (9) splice, during the concatenation, and two corners circular arc edge small square strip (9) are settled respectively in the left and right sides of a plurality of four corners circular arc edge small square strip two (8) assembly, form composite slab four (7) from this.

When the first composite board (1) and the second composite board (2) are combined into an integrated material, the first composite board (1) and the second composite board (2) are sequentially and crosswise spliced into a composite integrated material according to the thickness requirement.

Specific example 1:

the 10 square arc edge-falling small square strips I (4) are spliced to form a composite board III (3); when in splicing, glue is uniformly coated on the left and right planes (5) of the square strip I (4) with four corners and the circular strip I (4) are correspondingly bonded with each other and spliced into a composite board III (3), then wood long-direction stress relief treatment is carried out, namely the composite board III (3) is transversely cut into short materials with the length of 30-50CM according to a conventional method, and then the short materials are subjected to tooth milling and lengthening process treatment, so that the boards can be finger-spliced into composite boards III (3) with various lengths according to the use requirements, and then the upper surface and the lower surface of the composite board III (3) are processed into wavy arc profiles to obtain the composite board III (1).

The 9 square strips (8) with four corners and the 2 square strips (9) with two corners and the four corners are spliced in parallel according to the requirement to form a composite board IV (7); when in splicing, glue is uniformly smeared on the left plane II (10) and the right plane II (10) of the square strip II (8) with four corners and the glued left plane II (10) and the glued right plane II (10) of the square strip II (8) with four corners and the square strip II (9) with two corners are sequentially coated and parallelly arranged on the wide surface of the plane III (12) with the square strip II with two corners and are adhered and spliced in parallel to form a combined body, namely the composite board IV (7). Then, wood longitudinal stress relief treatment is carried out, namely, after the composite board IV (7) is transversely cut into short materials with the length of 30-50CM according to a conventional method, the composite board IV (7) with various lengths can be finger-jointed according to the use requirement through tooth milling and lengthening process treatment, and then the upper surface and the lower surface of the composite board IV (7) are simultaneously processed into wave arc profiles to obtain a composite board II (2).

When the 10-piece composite board I (1) and the 10-piece composite board II (2) are combined, glue is uniformly smeared on the wave arc profiles of the upper surface and the lower surface of the composite board I (1) and the composite board II (2) respectively, and then the 10-piece composite board I (1) and the 10-piece composite board II (2) are combined and spliced together, and when the 10-piece composite board I (1) and the composite board II (2) are combined, the wave arc profiles of the upper surface and the lower surface are correspondingly bonded, so that the composite board I and the composite board II (2) are combined into a strip-shaped solid wood composite integrated material.

Specific example 2:

the 20 square arc edge-falling small square strips I (4) are spliced to form a composite board III (3); when in splicing, glue is uniformly smeared on the left plane I and the right plane I (5) of the four-corner arc edge-falling small square strip I (4), and then the left plane I and the right plane I (5) of the four-corner arc edge-falling small square strip I (4) are correspondingly bonded with each other and spliced into a composite board III (3). Then, wood longitudinal stress relief treatment is carried out, namely, after the composite board III (3) is transversely cut into short materials with the length of 30-50CM according to a conventional method, the composite board III (3) with various lengths can be finger-jointed according to the use requirement through tooth milling and lengthening process treatment, and then the upper surface and the lower surface of the composite board III (3) are processed into wavy arc profiles to obtain a composite board I (1).

The 19 square strips (8) with four corners and the 2 square strips (9) with two corners and the four corners with the four corners and the two corners are spliced in parallel according to the requirement to form a composite board IV (7); when in splicing, glue is uniformly smeared on the left plane II (10) and the right plane II (10) of the square strip II (8) with four corners and the glued left plane II (10) and the glued right plane II (10) of the square strip II (8) with four corners and the square strip II (9) with two corners are sequentially coated and parallelly arranged on the wide surface of the plane III (12) with the square strip II with two corners and are adhered and spliced in parallel to form a combined body, namely the composite board IV (7). Then, wood longitudinal stress relief treatment is carried out, namely, after the composite board IV (7) is transversely cut into short materials with the length of 30-50CM according to a conventional method, the composite board IV (7) with various lengths can be finger-jointed according to the use requirement through tooth milling and lengthening process treatment, and then the upper surface and the lower surface of the composite board IV (7) are simultaneously processed into wave arc profiles to obtain a composite board II (2).

When the 20-piece composite board I (1) and the 20-piece composite board II (2) are combined, glue is uniformly smeared on the wave arc profiles of the upper surface and the lower surface of the composite board I (1) and the composite board II (2) respectively, and then the 20-piece composite board I (1) and the 20-piece composite board II (2) are combined and spliced together, and when the composite board I (1) and the composite board II (2) are combined, the wave arc profiles of the upper surface and the lower surface are correspondingly bonded, so that the composite board I and the composite board II (2) are combined into a strip-shaped solid wood composite integrated material.

Claims

1. The utility model provides a thin strip type wood composite integrated material which characterized in that: the laminated material consists of a first synthetic plate (1) and a second synthetic plate (2);

the first composite board (1) is formed by processing a third composite board (3), the third composite board (3) is formed by a plurality of small square strips (4) with four corners and circular arc falling edges, wherein the small square strips (4) with four planes (5) and four corners and circular arc surfaces (6) are spliced by the small square strips (4) with four corners and circular arc falling edges to form the third composite board (3), when the three composite boards are spliced, glue is uniformly smeared on the left and right planes (5) of the small square strips (4) with four corners and circular arc falling edges, then the left and right planes (5) of the small square strips with four corners and circular arc falling edges are correspondingly bonded with each other and spliced into the third composite board (3), then wood long-direction stress elimination treatment is carried out, namely after the third composite board (3) is transversely cut into short materials with the length of 30-50CM according to a conventional method, the composite board (3) with the length required by milling teeth and splicing process treatment is used, and then the upper surface of the third composite board (3) with the length required to be processed into the first composite board with the two arcs (1);

the composite board II (2) is formed by processing a composite board IV (7), and the composite board IV (7) consists of a plurality of square strips II (8) with four corners and two square strips 9 with two corners and circular edges; the square strip II (8) with four corner arc falling edges is provided with four planes II (10) and four corner arc surfaces II (11), the square strip (9) with two corner arc falling edges is provided with four planes III (12) and two corner arc surfaces (13), the square strip II (8) with the square strip (9) with two corner arc falling edges is spliced, and when the square strip is spliced, the square strip (9) with two corner arc falling edges is respectively arranged at the left side and the right side of the square strip II (8) combination body with the four corner arc falling edges, so that a composite board IV (7) is formed; the method comprises the steps of firstly uniformly coating glue on left and right planes (10) of a square strip II (8) with four corners and arc edges, then arranging the glued left and right planes (10) of the square strip II (8) with the four corners in parallel, and then coating and arranging the broad faces of planes (12) of square strips (9) with two corners and arc edges in parallel in turn to enable the planes to be bonded and spliced into a combined body in parallel, so that a composite board IV (7) is formed; then, wood longitudinal stress relief treatment is carried out, namely, after the composite board IV (7) is transversely cut into short materials with the length of 30-50CM according to a conventional method, the composite board IV (7) with various lengths is finger-jointed through tooth milling and lengthening process treatment according to the use requirement, and then the upper surface and the lower surface of the composite board IV (7) are simultaneously processed into a wavy arc surface to obtain a composite board II (2);

the four-corner arc edge-falling small square strips I (4) and the four-corner arc edge-falling small square strips II (8) are realized by directly adopting a thin-strip cylindrical wood mandrel with the diameter of 2-3CM to plane out four planes of very few parts through low-power simple four-side planing; the two-angle arc edge-falling small square strip (9) is realized by directly adopting a four-angle arc edge-falling small square strip I (4) or a four-angle arc edge-falling small square strip II (8) which is longitudinally divided into two parts;

when the first composite board (1) and the second composite board (2) are combined into an integrated material, the first composite board (1) and the second composite board (2) are sequentially combined and spliced into a thin strip-shaped solid wood composite integrated material according to the thickness requirement, when the integrated material is combined, glue is uniformly smeared on the wavy arc profiles on the upper surface and the lower surface of the first composite board (1) and the second composite board (2), and then the first composite board (1) and the second composite board (2) are combined and spliced together, and when the integrated material is spliced, the wavy arc profiles on the upper surface and the lower surface of the first composite board (1) and the second composite board (2) are correspondingly bonded, so that the integrated material is combined into the thin strip-shaped solid wood composite integrated material; the connecting surfaces of the first synthetic plate (1) and the second synthetic plate (2) are wavy cambered surfaces, when the two plates are synthesized, the splicing and bonding area is larger, the bonding of the plates is firmer, and the dislocation bonding of the original splicing points of the first synthetic plate (1) and the second synthetic plate (2) is realized after the first synthetic plate (1) and the second synthetic plate (2) are compositely spliced, so that the strength of the plates is improved.