CN218953728U - Three-plate-body crossed mortise and tenon joint structure and X-shaped tea table thereof - Google Patents

Abstract

The utility model discloses a three-plate body crossed mortise and tenon joint structure, which comprises a main plate body, wherein a plurality of joint grooves are formed in the main plate body, and a first check block and a second check block are arranged in the joint grooves; the novel combined type split board comprises a first split board body and a second split board body, wherein the first split board body and the second split board body are positioned on two sides of a main board body, a plurality of first splicing blocks are arranged on one side, close to a splicing groove, of the first split board body, a plurality of second splicing blocks are arranged on one side, close to the splicing groove, of the second split board body, the first splicing blocks are provided with first non-return grooves at positions corresponding to the first non-return blocks, and the second splicing blocks are provided with second non-return grooves at positions corresponding to the second non-return blocks.

Description

Three-plate-body crossed mortise and tenon joint structure and X-shaped tea table thereof

Technical Field

The utility model relates to the technical field of furniture adopting mortise and tenon joint structures, in particular to a three-plate body crossed mortise and tenon joint structure and an X-shaped tea table thereof.

Background

At present, in the component parts of common furniture, an X-shaped modeling part is a comparatively large number of modeling parts, such as tea table legs, bookshelf, storage rack and the like, but most of the existing structures for assembling the X-shaped modeling part adopt the fixing mode of screws, hinges and adapter parts of European furniture manufacturing methods, the fixing parts are exposed, the metal parts rust easily to cause product durability and the like, and the later repair rate is high.

Disclosure of Invention

In order to overcome the defects in the prior art, the utility model aims to provide a three-plate body crossed mortise and tenon joint structure and an X-shaped tea table thereof, so as to solve the technical problems in the background art.

In order to solve the technical problems, the utility model adopts the following technical scheme:

a three plate body crossing mortise and tenon joint structure, comprising:

the main board body is provided with a plurality of splicing grooves, and a first check block and a second check block are arranged in the splicing grooves;

the first board body and the second board body that divide, first board body and second board body are located the both sides of mainboard body, one side that first board body is close to the splice groove is equipped with a plurality of first splice piece, one side that the second board body is close to the splice groove is equipped with a plurality of second splice piece, first splice piece is equipped with first check groove in the position that corresponds first check piece, the second splice piece is equipped with the second check groove in the position that corresponds the second check piece, when two board bodies are inserted the splice inslot from the both sides of mainboard body respectively, relies on respective check groove and the mortise-tenon joint of the check piece mutual card realization three plate body that corresponds.

The first splicing block is positioned on the lower end face of the first split plate body, the second splicing block is positioned on the upper end face of the second split plate body, the sum of the thicknesses of the first splicing block and the second splicing block is just equal to the height of the splicing groove, and the lengths of the first splicing block and the second splicing block are equal to the length of the splicing groove.

The first check block is located at an inner side position of one side of the splicing groove, which is close to the upper part of the first split plate body, the second check block is located at an inner side position of one side of the splicing groove, which is close to the lower part of the second split plate body, the first check block is located at the outer side of the joint of the first splicing block and the first split plate body, and the second check block is located at the outer side of the joint of the second splicing block and the second split plate body.

The two first check blocks are respectively located at two inner side positions, close to one side upper portion of the first split plate body, of the splicing groove, the two second check blocks are respectively located at two inner side positions, close to one side lower portion of the second split plate body, of the splicing groove, the two first check grooves are respectively located at two outer side positions of the joint of the first split plate body and the first split plate body, and the two second check grooves are respectively located at two outer side positions of the joint of the second split plate body and the second split plate body.

The main board body is perpendicular to the first sub-board body and the second sub-board body.

An X-shaped tea table comprises the three-plate body crossed mortise and tenon joint structure, wherein the upper end of the main plate body or the second sub-plate body extends to the horizontal direction to form a tea table surface, an included angle area between the main plate body and the upper end part of the second sub-plate body forms a storage frame, and the lower end parts of the first sub-plate body and the main plate body form supporting legs.

Compared with the prior art, the utility model has the beneficial effects that:

(1) According to the utility model, the mortise and tenon joint structure between the two split plate bodies and the main plate body can be spliced, so that the spliced part is hidden, no spliced part is exposed, the traditional mortise and tenon joint structure is utilized for assembly, the durability of the product is stronger, and the later repair rate is greatly reduced.

(2) The utility model skillfully utilizes the splice blocks of the two split plate bodies to be inserted into the splice grooves, and then upwards or downwards utilizes the respective check grooves and the check blocks to mutually clamp, so that mortise and tenon closure is completed, and the assembly is simple.

Drawings

Fig. 1: the three-plate body crossed mortise and tenon joint structure is an exploded view I;

fig. 2: the second exploded view is a three-plate body crossed mortise and tenon joint structure;

fig. 3: the utility model relates to a perspective view of a three-plate body crossed mortise and tenon joint structure;

fig. 4: an enlarged view of the utility model at a in fig. 3;

fig. 5: the first split plate schematic diagram is hidden for the three-plate crossed mortise and tenon joint structure;

fig. 6: the side view (the decomposition state) of the three-plate body crossed mortise and tenon joint structure is provided;

fig. 7: the side view angle perspective (the exploded state) of the three-plate body crossed mortise and tenon joint structure is provided;

fig. 8: the side view angle perspective (assembly state) of the three-plate body crossed mortise and tenon joint structure is provided;

fig. 9: the three-plate body is a three-dimensional view of a three-plate body crossed mortise and tenon joint structure;

fig. 10: the structure of the X-shaped tea table is schematically shown;

fig. 11: the side view I of other furniture structures derived from the three-plate body crossed mortise and tenon joint structure is provided;

fig. 12: the side view II is the side view of other furniture structures derived from the three-plate body crossed mortise and tenon joint structure;

fig. 13: the side view of other furniture structures derived from the three-plate body crossed mortise and tenon joint structure is three;

fig. 14: the side view of other furniture structures derived from the three-plate body crossed mortise and tenon joint structure is four;

in the figure: the main board body 1, the splicing groove 103, the first check block 101, the second check block 102, the first sub board body 2, the second sub board body 3, the first splicing block 201, the second splicing block 301, the first check groove 202 and the second check groove 302.

Detailed Description

The present utility model will be further described with reference to the accompanying drawings and detailed description, wherein it is to be understood that, on the premise of no conflict, the following embodiments or technical features may be arbitrarily combined to form new embodiments.

Referring to fig. 1-14:

example 1: referring to fig. 1-4, the embodiment discloses a three-plate body crossed mortise and tenon joint structure, which comprises a main plate body 1, wherein a plurality of joint grooves 103 are formed in the main plate body 1, and a first check block 101 and a second check block 102 are arranged in the joint grooves 103; still include first minute plate body 2 and second minute plate body 3, first minute plate body 2 and second minute plate body 3 are located the both sides of mainboard body 1, one side that first minute plate body 2 is close to splice groove 103 is equipped with the first splice block 201 of a plurality of, one side that second minute plate body 3 is close to splice groove 103 is equipped with the second splice block 301 of a plurality of, and the quantity of first splice block 201 and second splice block 301 can be based on X shape molding part size, and furniture size is decided, generally, and at least one also can realize, and the quantity is more then more firm, first splice block 201 is equipped with first check groove 202 in the position that corresponds first check block 101, second splice block 301 is equipped with second check groove 302 in the position that corresponds second check block 102, relies on respective check groove and the mortise and tenon interconnect of corresponding check block realization three plate body when two minute plate bodies insert splice groove 103 in the both sides of mainboard body 1 respectively.

Referring to fig. 4, the first splice block 201 is located at the lower end surface of the first sub-plate body 2, the second splice block 301 is located at the upper end surface of the second sub-plate body 3, the sum of the thicknesses of the first splice block 201 and the second splice block 301 is just equal to the height of the splice groove 103, the lengths of the first splice block 201 and the second splice block 301 are equal to the length of the splice groove 103, when the mortise and tenon joints are connected, the first splice block 201 enters from the upper end of the splice groove 103 and moves downwards to be mutually blocked with the first check block 101, and the second splice block 301 enters from the lower end of the splice groove 103 and moves upwards to be mutually blocked with the second check block 102.

Referring to fig. 4, the first check block 101 is located at an upper inner side position of the splice groove 103 near the first split plate body 2, the second check block 102 is located at a lower inner side position of the splice groove 103 near the second split plate body 3, the first check groove 202 is located at an outer side of a junction between the first splice block 201 and the first split plate body 2, and the second check groove 302 is located at an outer side of a junction between the second splice block 301 and the second split plate body 3.

Referring to fig. 4, the two first check blocks 101 are respectively located at two inner side positions in the splice groove 103 near the upper part of one side of the first split plate body 2, the two second check blocks 102 are respectively located at two inner side positions in the splice groove 103 near the lower part of one side of the second split plate body 3, the two first check grooves 202 are respectively located at two outer side positions at the joint of the first splice block 201 and the first split plate body 2, and the two second check grooves 302 are respectively located at two outer side positions at the joint of the second splice block 301 and the second split plate body 3.

During splicing, the first splicing block 201 of the first split plate body 2 and the second splicing block 301 of the second split plate body 3 should be simultaneously inserted into the splicing groove 103, the oblique angle is further needed to be inserted, the preferred angle is that the free end of the first split plate body 2 is upward, the first splicing block 201 is obliquely downward to enter the splicing groove 103, the free end of the second split plate body 3 is downward, the second splicing block 301 is obliquely upward to enter the splicing groove 103, when the two splicing blocks are bumped together in the splicing groove 103, the first split plate body 2 is then upwards and simultaneously pulled up by a certain angle, the second split plate body 3 is then downwards and simultaneously pulled up by a certain angle, at this moment, the two splicing blocks are separated from and collide in the splicing groove 103, then the first splicing block 201 is obliquely and obliquely pushed into the splicing groove 103 until the position of the first non-return groove 202 is just aligned with the first non-return block 101, the first non-return groove 202 is clamped with the first non-return block 101, the second splicing block 301 is obliquely upward to enter the splicing groove 103, the second splicing block 201 is simultaneously pushed into the splicing groove 302, the second non-return groove is also needed to be simultaneously pulled up by the second splicing block 301, the second splicing block 302 is correspondingly pushed up by the second non-return groove 302, and the two splicing blocks are simultaneously pushed up by the second splicing block 101, and the two splicing blocks are simultaneously clamped by the two splicing blocks are simultaneously pushed up by the adhesive tape, and the two splicing blocks are simultaneously pushed up by the two splicing blocks, the two splicing blocks are simultaneously pushed up by the two opposite directions, and the first splicing block are correspondingly, and the first splicing block are correspondingly matched with the first splicing block and the first splicing block are correspondingly, and the first splicing block and the splicing block are correspondingly fixedly connected with the splicing block and the splicing block are fixedly connected with the splicing block.

Referring to fig. 7 to 8, in particular, in actual operation and design, the main board body 1 is generally perpendicular to the first board body 2 and the second board body 3, and the two board bodies can be quickly abutted with the main board body 1 by the angle of perpendicular design, and if the two board bodies are designed to be other angles, the angle of the splice groove 103 and the angle of the splice block, the inclined plane and the like need to be redesigned, which is more complex, and certainly can be realized.

Referring to fig. 10, the utility model also discloses an X-shaped tea table, which comprises the three-plate body crossed mortise-tenon joint structure, wherein the upper end of the main plate body 1 or the second sub-plate body 3 extends horizontally to form a tea table surface, an included angle area between the upper end parts of the main plate body 1 and the second sub-plate body 3 forms a storage frame, and the lower end parts of the first sub-plate body 2 and the main plate body 1 form supporting legs.

Referring to fig. 11-14, in addition, according to the extension of the X-shaped tea table, the structure can be applied to various furniture such as tables, shelves, lockers, chairs, etc., but is not limited to a certain furniture.

The above embodiments are only preferred embodiments of the present utility model, and the scope of the present utility model is not limited thereto, but any insubstantial changes and substitutions made by those skilled in the art on the basis of the present utility model are intended to be within the scope of the present utility model as claimed.

Claims (6)

1. Three plate body alternately mortise and tenon mosaic structure, its characterized in that: comprising the following steps:

the main board body is provided with a plurality of splicing grooves, and a first check block and a second check block are arranged in the splicing grooves;

the first board body and the second board body that divide, first board body and second board body are located the both sides of mainboard body, one side that first board body is close to the splice groove is equipped with a plurality of first splice piece, one side that the second board body is close to the splice groove is equipped with a plurality of second splice piece, first splice piece is equipped with first check groove in the position that corresponds first check piece, the second splice piece is equipped with the second check groove in the position that corresponds the second check piece, when two board bodies are inserted the splice inslot from the both sides of mainboard body respectively, relies on respective check groove and the mortise-tenon joint of the check piece mutual card realization three plate body that corresponds.

2. The three-plate body crossed mortise and tenon joint structure as claimed in claim 1, wherein: the first splicing block is positioned on the lower end face of the first split plate body, the second splicing block is positioned on the upper end face of the second split plate body, the sum of the thicknesses of the first splicing block and the second splicing block is just equal to the height of the splicing groove, and the lengths of the first splicing block and the second splicing block are equal to the length of the splicing groove.

3. The three-plate body crossed mortise and tenon joint structure as claimed in claim 2, wherein: the first check block is located at an inner side position of one side of the splicing groove, which is close to the upper part of the first split plate body, the second check block is located at an inner side position of one side of the splicing groove, which is close to the lower part of the second split plate body, the first check block is located at the outer side of the joint of the first splicing block and the first split plate body, and the second check block is located at the outer side of the joint of the second splicing block and the second split plate body.

4. The three-plate body crossed mortise and tenon joint structure as claimed in claim 2, wherein: the two first check blocks are respectively located at two inner side positions, close to one side upper portion of the first split plate body, of the splicing groove, the two second check blocks are respectively located at two inner side positions, close to one side lower portion of the second split plate body, of the splicing groove, the two first check grooves are respectively located at two outer side positions of the joint of the first split plate body and the first split plate body, and the two second check grooves are respectively located at two outer side positions of the joint of the second split plate body and the second split plate body.

5. A three-plate body crossed mortise and tenon joint structure as defined in any one of claims 1 to 4, characterized in that: the main board body is perpendicular to the first sub-board body and the second sub-board body.

6. An X-shaped tea table, which is characterized by comprising the three-plate body crossed mortise-tenon joint structure according to any one of claims 1-5, wherein the upper end of the main plate body or the second sub-plate body extends horizontally to form a tea table surface, an included angle area between the main plate body and the upper end part of the second sub-plate body forms a storage frame, and the lower end parts of the first sub-plate body and the main plate body form supporting legs.

Images