CN212407208U - Frame splicing structure - Google Patents

Abstract

The embodiment of the utility model provides a framework mosaic structure relates to section bar concatenation technical field. The frame splicing structure comprises a first section bar, a second section bar and splicing pieces. The first section bar is provided with a first inner cavity, and the end part of the first section bar is provided with a first clamping hole. The second section bar is provided with a second inner cavity, and the end part of the second section bar is provided with a second clamping hole. The splicing piece comprises a first connecting body and a second connecting body which are fixedly connected, wherein the first connecting body extends along a first direction, and the second connecting body extends along a second direction. The first connecting body comprises a first elastic buckle, and the second connecting body comprises a second elastic buckle. The first connecting body is embedded in the first inner cavity, the first elastic buckle is clamped with the first clamping hole, the second connecting body is embedded in the second inner cavity, and the second elastic buckle is clamped with the second clamping hole. This framework mosaic structure detains through first elasticity and first section bar joint, and second elasticity is detained and second section bar joint to realize fixed concatenation, convenient assembling has improved assembly efficiency greatly.

Description

Frame splicing structure

Technical Field

The utility model belongs to the technical field of the section bar concatenation, more specifically relates to a framework mosaic structure.

Background

When the frame body structure (such as a mirror frame, a mirror cabinet, a door window and the like) is produced and manufactured by using the sectional materials, a 45-degree splicing mode is often adopted through an angle code. At present, the following two production methods are mostly adopted:

firstly, a section bar is fixedly connected with an angle bracket by screws;

and secondly, bonding the sectional material and the corner connector by using glue.

However, any of the above methods has a problem of low production efficiency.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a framework mosaic structure to improve the problem that production efficiency is low when using section bar preparation framework structure, for example.

The embodiment of the utility model discloses a can realize like this:

in a first aspect, a frame splicing structure is provided, which comprises a first section bar, a second section bar and a splicing piece; the first section bar is provided with a first inner cavity, and the end part of the first section bar is provided with a first clamping hole; the second section bar is provided with a second inner cavity, and the end part of the second section bar is provided with a second clamping hole; the splicing piece comprises a first connecting body and a second connecting body which are fixedly connected, the first connecting body extends along a first direction, the second connecting body extends along a second direction, the first connecting body comprises a first elastic buckle, and the second connecting body comprises a second elastic buckle; the first connecting body is embedded in the first inner cavity, the first elastic buckle is clamped with the first clamping hole, the second connecting body is embedded in the second inner cavity, and the second elastic buckle is clamped with the second clamping hole.

The embodiment of the utility model provides a through set up first joint hole on first section bar, set up second joint hole on the second section bar, set up first elasticity on the splice and detain and second elasticity is detained. Wherein, first elasticity is buckled with the first joint hole joint of first section bar, and second elasticity is buckled with the second joint hole joint of second section bar.

According to the first elastic buckle and the second elastic buckle, elastic deformation can occur under the action of external force, and after the external force disappears, the first elastic buckle and the second elastic buckle can recover the characteristics of the initial state. The first section bar and the second section bar are respectively clamped with the splicing pieces, and the first section bar and the second section bar are not easy to separate after being clamped. On the premise of not needing to use screw connectors or glue, the frame splicing structure is convenient to assemble, and the installation efficiency of the frame splicing structure is improved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic structural diagram of a frame splicing structure provided by an embodiment of the present invention;

fig. 2 is an exploded schematic view of a frame splicing structure provided by an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a first view angle of a first section bar in the frame splicing structure provided by the embodiment of the present invention;

fig. 4 is a schematic structural diagram of a second view angle of the first section bar in the frame splicing structure provided by the embodiment of the present invention;

fig. 5 is a schematic structural diagram of a third view angle of the first section bar in the frame splicing structure provided by the embodiment of the present invention;

fig. 6 is a schematic structural diagram of a second profile in the frame splicing structure provided by the embodiment of the present invention;

fig. 7 is a schematic structural view of a first view angle of a splicing member in the frame splicing structure according to the embodiment of the present invention;

fig. 8 is a schematic structural view of a second view angle of the splicing member in the frame splicing structure according to the embodiment of the present invention;

FIG. 9 is an enlarged view of A in FIG. 7;

fig. 10 is a schematic structural view of a third view angle of the splicing member in the frame splicing structure according to the embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.

It should be noted that the features of the embodiments of the present invention may be combined with each other without conflict.

The section bar is an object with a certain section shape and size, which is made of iron or steel and materials with certain strength and toughness through plastic processing (such as rolling, extrusion, casting and other processes). The section bar has various varieties and specifications and wide application, and plays a very important role in rolling production. The section bar can be used independently and can be further processed into other manufactured products.

The section bar has the advantages of flexible assembly, rapid installation, convenient transportation, beautiful appearance, practicality and the like. At present, profiles are often used in the production of building structures or frame-like products. People can select parameters such as specific shape, material, heat treatment state, mechanical property and the like of the section bar according to design requirements, and then the section bar is subjected to operations such as segmentation, splicing and the like according to specific size and shape requirements, and finally the required structural product is obtained.

At present, when frame structures (such as mirror frames, mirror cabinets, doors and windows, bathroom doors, bathroom furniture door frames, door cabinets and the like) are produced and manufactured by using sectional materials, a 45-degree splicing mode is mostly adopted by means of corner connectors, and the existing splicing method is as follows:

firstly, two sectional materials forming an angle with each other are fixedly connected with an angle connector by adopting fasteners such as screws and the like;

and secondly, adopting glue to bond and fix two sections forming an angle with the angle connector.

However, in the first method, the corner brace and the corresponding position of the section bar need to be subjected to finish machining for many times (such as drilling, forming threaded holes and the like); due to the structural characteristics of the section of the sectional material, the difficulty of screw assembly is high; resulting in low assembly efficiency and difficulty in achieving desired assembly effects, thereby affecting the aesthetic appearance of the product.

Aiming at the second method, glue is adopted for fixing, and compared with a screw fixing mode, the method is simple to operate. However, the method has a large demand for glue, and the assembly can be smoothly carried out only by means of a special tool during assembly; in addition, the curing time of the glue after the assembly is finished is long, and the curing time is inconsistent, so that the production efficiency is low.

Based on the above problem, please refer to fig. 1 and fig. 2, an embodiment of the present invention provides a frame splicing structure 100, which can be applied to, but not limited to: products such as picture frame, mirror cabinet, door and window, bathroom door, bathroom furniture door frame, door cabinet, this application does not use this as the limit, and the user is decided according to the in-service use demand.

The frame splicing structure 100 includes a first section bar 110, a second section bar 120 and a splicing element 130.

Wherein, the splicing element 130 is provided with a first elastic buckle 1313 and a second elastic buckle 1333. In the assembling process, according to the principle that the first elastic buckle 1313 and the second elastic buckle 1333 are elastically deformed under the action of external force and recover to the initial state after the external force disappears, the splicing element 130 is clamped and fixed with the first profile 110 through the first elastic buckle 1313 and is clamped and fixed with the second profile 120 through the second elastic buckle 1333. In the assembling process, screws or glue do not need to be adopted, the assembling is convenient, and the assembling efficiency is greatly improved.

The following describes the frame splicing structure 100 according to an embodiment of the present invention in detail.

First, a specific structure of the first profile 110 will be described in detail.

Referring to fig. 3, 4 and 5, the first section bar 110 is an elongated rod-shaped structure, and the first section bar 110 has a first inner cavity 111 extending along a length direction. The first inner cavity 111 is a through hole, and a first clamping hole 112 for clamping with the splicing member 130 is formed at an end of the first section bar 110.

Specifically, the first profile 110 includes a first side surface 113 and a second side surface 114 opposite to each other in the width direction, and a first end surface 115 and a second end surface 116 opposite to each other in the length direction. The length dimension of the first side surface 113 is greater than the length dimension of the second side surface 114, and the first end surface 115 and the second end surface 116 respectively form an acute angle with the first side surface 113.

When the first profile 110 and the second profile 120 are joined together by the joining member 130 to form a frame, the first side 113 is the side of the frame facing outward, the second side 114 is the side of the frame facing inward, and the first end 115 and the second end 116 are the mating surfaces of two adjacent profiles when joined together.

In the frame splicing structure 100 provided by this embodiment, the included angles between the first end surface 115, the second end surface 116 and the first side surface 113 are determined according to the structural requirements of the frame (for example, a rectangular frame).

Optionally, included angles formed between the first end surface 115 and the first side surface 113 and between the second end surface 116 and the first side surface 113 are both 45 °, and the first inner cavity 111 penetrates through the first end surface 115 and the second end surface 116 along the length direction of the first profile 110.

The first section bar 110 and the splicing element 130 are easy to install and the outer surface is not visible after being spliced. Optionally, the first engaging hole 112 is opened on a side of the first section bar 110 facing away from the first side surface 113. After the first section bar 110 and the second section bar 120 are spliced into the frame structure through the splicing piece 130, the first clamping hole 112 is hidden inside the frame structure, and is not easy to see from the outer surface of the frame structure, which is beneficial to improving the aesthetic property of the product.

Optionally, the shape of the first engaging hole 112 may be regular, such as rectangular, circular, polygonal, etc., or irregular. Specifically, it is determined according to the actual process, so long as the first engaging hole 112 is ensured to be matched with the first elastic buckle 1313 of the splicing element 130. On the premise that the first clamping hole 112 is convenient to process and assemble, optionally, the first clamping hole 112 is rectangular or circular.

Optionally, the first section bar 110 further includes a first positioning portion 117 along the length direction, as shown in fig. 3, the first positioning portion 117 is disposed on the peripheral wall of the first inner cavity 111, and is disposed in a protruding manner or a recessed manner relative to the peripheral wall of the first inner cavity 111. When the splicing member 130 is assembled with the first section bar 110, the splicing member 130 is spliced in place along the width direction of the first section bar 110 by the first positioning portion 117, and the phenomenon of left-right shaking is not easy to occur.

Optionally, the first positioning portion 117 is protruded from the peripheral wall of the first cavity 111 along the length direction of the first profile 110.

Next, the structure of the second profile 120 is described, and as shown in fig. 6, the second profile 120 is an elongated rod-like structure. The second profile 120 has a second cavity 121 extending in a length direction. The second inner cavity 121 is a through hole, and a second fastening hole 123 for fastening with the splicing member 130 is provided at the end of the second profile 120.

Optionally, the second profile 120 further includes a second positioning portion 125 along the length direction, and the second positioning portion 125 is located on the peripheral wall of the second cavity 121 and is disposed in a protruding manner or a recessed manner relative to the peripheral wall of the second cavity 121.

Optionally, the structure and the cross-sectional shape of the second section bar 120 are the same as or similar to those of the first section bar 110, and the present invention is not limited thereto, and is specifically determined according to actual requirements. As long as it is satisfied that the second section bar 120 and the first section bar 110 can be spliced into a frame-like structure such as a mirror frame or a mirror cabinet through the splicing member 130.

In order to reduce the processing difficulty and improve the assembly efficiency, optionally, the structure, the cross-sectional shape and the size of the second profile 120 are respectively the same as those of the first profile 110. For a detailed structure of the second section bar 120, please refer to the structure description of the first section bar 110, which is not described herein.

Again, the specific structure of the splicing element 130 will be described in detail.

Referring to fig. 7 to 10, the splicing member 130 includes a first connecting body 131 and a second connecting body 133 which are fixedly connected. The first connecting body 131 extends along the first direction 101, the second connecting body 133 extends along the second direction 103, the first connecting body 131 includes a first elastic buckle 1313, and the second connecting body 133 includes a second elastic buckle 1333.

During splicing and assembling, the first connecting body 131 is inserted into the first inner cavity 111 of the first section bar 110 and is clamped with the first clamping hole 112 of the first section bar 110 through the first elastic buckle 1313. The second connecting body 133 is inserted into the second inner cavity 121 of the second section bar 120, and is fastened to the second fastening hole 123 through the second elastic fastener 1333. Thereby realizing the splicing assembly of the first profile 110 and the second profile 120 by the splicing member 130.

In order to improve the splicing effect of the first profile 110 and the second profile 120 and the stability after the splicing is finished. Optionally, the shape of the cross section of the splicing element 130 is substantially the same as or consistent with the shape of the first inner cavity 111 of the first profile 110, and is not limited herein, depending on actual requirements.

As shown in fig. 2, in the present embodiment, the first profile 110 and the second profile 120 have the same cross-sectional shape and are both L-shaped.

Optionally, the splicing element 130 further includes a splicing main body 135 corresponding to the first and second profiles 110 and 120. The splicing main body 135 is fixedly connected to the first connection body 131 and the second connection body 133 at the same time, and the splicing main body 135 is located on the same side of the first connection body 131 and the second connection body 133. The splice body 135 is fixedly connected to the first connection body 131 and has an L-shaped cross section to be better matched with the first inner cavity 111 of the first profile 110. The joint body 135 is fixedly connected to the second connecting body 133 to form an L-shaped cross section, so as to be better matched with the second cavity 121 of the second profile 120.

Optionally, the first connecting body 131, the second connecting body 133 and the splicing main body 135 are integrally formed by an injection molding process. The first direction 101 and the second direction 103 are perpendicular to each other, and the spliced mirror frame is rectangular.

As shown in fig. 2 and 7, in particular, the first connecting body 131 includes a first connecting body 1311 and a first elastic buckle 1313, and the first connecting body 1311 is fixedly connected to the splice main body 135 and forms a structure with an L-shaped cross section. One end of the first elastic buckle 1313 is connected to the first connecting body 1311, the other end of the first elastic buckle 1313 extends in a direction opposite to the first direction 101, and a first elastic gap 1315 is formed between the other end of the first elastic buckle 1313 and the first connecting body 1311. So that the first elastic clasp 1313 has the ability to elastically deform when subjected to an external force.

The second connection body 133 includes a second connection body 1331 and a second elastic buckle 1333. The second connection body 1331 is fixedly connected to the splicing main body 135 and forms a structure with an L-shaped cross section. One end of the second elastic buckle 1333 is connected to the second connection body 1331, the other end of the second elastic buckle 1333 extends in the direction opposite to the second direction 103, and a second elastic gap 1335 is formed between the other end of the second elastic buckle 1333 and the second connection body 1331, so that the second elastic buckle 1333 has the capability of elastic deformation when being subjected to an external force.

Referring to fig. 7 and 8, in particular, the first connecting body 1311 includes a first inserting portion 13111, a first clamping portion 13113 and a first matching portion 13115, which are connected in sequence; the second connecting body 1331 includes a second inserting portion 13311, a second clamping portion 13313 and a second matching portion 13315 which are connected in sequence, and one end of the first matching portion 13115 far away from the first clamping portion 13113 is connected with one end of the second matching portion 13315 far away from the second clamping portion 13313.

The first clamping portion 13113 is recessed relative to the first insertion portion 13111 and the first mating portion 13115, and the first elastic buckle 1313 is connected to the first insertion portion 13111 and extends toward the first mating portion 13115. First elastic gaps 1315 are formed between the first elastic buckles 1313 and the first clamping portions 13113 and the first matching portions 13115, and the first elastic gaps 1315 provide deformation space for the first elastic buckles 1313 to elastically deform when being subjected to external force.

The second clamping portion 13313 is recessed relative to the second insertion portion 13311 and the second fitting portion 13315, and the second elastic buckle 1333 is connected to the second insertion portion 13311 and extends toward the second fitting portion 13315. Second elastic gaps 1335 are formed between the second elastic buckle 1333 and the second clamping portion 13313 and the second matching portion 13315, and the second elastic gaps 1335 provide deformation space for the second elastic buckle 1333 to deform elastically when being subjected to external force.

Optionally, when the first engaging hole 112 of the first section bar 110 is opened at a side away from the first side surface 113, and the second engaging hole 123 of the second section bar 120 is opened at a position similar to that of the first section bar 110, the first engaging hole is engaged with the second engaging hole. Optionally, the first elastic buckle 1313 is located on one side of the first connection body 1311 close to the second connection body 1331, and the second elastic buckle 1333 is located on one side of the second connection body 1331 close to the first connection body 1311. When the first profile 110 and the second profile 120 are spliced by the splicing member 130, the first elastic buckle 1313 and the second elastic buckle 1333 are both located on the inner side of the frame, and the outer side is not visible, which is beneficial to improving the aesthetic property of the frame.

Referring to fig. 9, in particular, the first elastic buckle 1313 includes a first elastic body 13131 and a first bump 13133.

The first elastic body 13131 is connected to the first insertion portion 13111 and extends toward the first matching portion 13115, and the first protrusion 13133 is protruded from a side of the first elastic body 13131 away from the first clamping portion 13113.

The first elastic body 13131 has a tendency to be elastically deformed when an external force is applied thereto. When the first connecting body 131 is engaged with the first section bar 110, the first protrusion 13133 of the first elastic buckle 1313 is pressed by the peripheral wall of the first inner cavity 111, so that the first elastic body 13131 is driven to deflect toward one side of the first engaging portion 13113, that is, the first elastic buckle 1313 is elastically deformed. When the first protrusion 13133 moves to match with the first engaging hole 112 of the first profile 110 under the action of external force, the first protrusion 13133 is engaged with the first engaging hole 112, the extrusion force disappears, and the first elastic body 13131 recovers to the original state, thereby completing the engaging assembly of the first connecting body 131 and the first profile 110.

Similarly, the second elastic buckle 1333 includes a second elastic body 13331 and a second protrusion 13333 protruding from the second elastic body 13331. The second elastic body 13331 has a tendency of elastic deformation under the action of external force, and when the second connector 133 and the second profile 120 are in snap fit, the second protrusion 13333 is pressed by the peripheral wall of the second cavity 121 to drive the second elastic body 13331 to deflect, i.e. the second elastic buckle 1333 is elastically deformed. When the second protrusion 13333 moves to be matched with the second clamping hole 123 of the second profile 120 under the action of external force, the second protrusion 13333 is clamped at the position of the second clamping hole 123, the extrusion acting force disappears, and the second elastic body 13331 recovers to the initial state, thereby completing the clamping assembly of the second connector 133 and the second profile 120.

In order to realize the purposes of convenient clamping and difficult disengagement after clamping. Optionally, the first bump 13133 is located at an end of the first elastic body 13131 away from the first embedding portion 13111, which is beneficial to saving labor during the clamping process. In addition, the first tab 13133 includes a first guiding inclined surface 13135, and an included angle between the first guiding inclined surface 13135 and the first direction 101 is an obtuse angle. In the assembling process, under the action of external force, the peripheral wall of the first inner cavity 111 of the first section bar 110 relatively moves along the first guide inclined surface 13135, so that the first elastic buckle 1313 and the first section bar 110 are conveniently clamped, and the reverse buckle structure is formed after clamping and is not easy to separate. Similarly, the second protrusion 13333 includes a second guiding inclined surface 13335, and an included angle between the second guiding inclined surface 13335 and the second direction 103 is an obtuse angle, so that the second elastic buckle 1333 and the second profile 120 are conveniently clamped, and an effect that the inverted buckle structure is not easy to be disengaged is formed after clamping.

Optionally, the first profile 110 and the second profile 120 are spliced into a rectangular frame structure by a splicing member 130, and the splicing position of the first profile 110 and the second profile 120 is a 45 ° splicing manner.

Specifically, the splice body 135 includes a first splice 1351 and a second splice 1353.

The first splicing portion 1351 corresponds to the first connection body 131, and the second splicing portion 1353 corresponds to the second connection body 133. The intersection of the first and second splices 1351, 1353 is a 45 ° hypotenuse, and is spliced into a right angle configuration. Wherein the first splice 1351 extends in the first direction 101 and the second splice 1353 extends in the second direction 103.

In the splicing assembly, the first splicing portion 1351 and the first connecting body 131 are adapted to cooperate with the first cavity 111 of the first profile 110, and the second splicing portion 1353 and the second connecting body 133 are adapted to cooperate with the second cavity 121 of the second profile 120.

With continued reference to fig. 2 and 7, to achieve a smooth assembly of the splice 130 with the first and second profiles 110, 120. Optionally, in match with the first profile 110, the first splicing portion 1351 is provided with a first guiding portion 1352; the second splicing portion 1353 is provided with a second guide portion 1354 to be matched with the second profile 120.

The first guiding portion 1352 is disposed on a side of the first splicing portion 1351 away from the first connecting body 131, and the first guiding portion 1352 is matched with the first positioning portion 117 of the first profile 110. The second guiding portion 1354 is disposed on a side of the second splicing portion 1353 away from the second connecting body 133, and the second guiding portion 1354 is engaged with the second positioning portion 125 of the second profile 120.

Optionally, one of the first positioning portion 117 and the first guiding portion 1352 is a groove, and the other is a rib, and the rib is embedded in the groove to achieve the guiding function. Similarly, one of the second positioning portion 125 and the second guiding portion 1354 is a groove, and the other is a rib, and the rib is embedded in the groove to achieve the guiding function.

In order to improve the aesthetic appearance of the first and second profiles 110 and 120 after being spliced by the splicing member 130, as shown in fig. 1 and 9, the splicing member 130 further includes a corner transition portion 137. The corner positions of the first profile 110 and the second profile 120 after being spliced are completed through the corner transition portion 137.

Specifically, the corner transition portion 137 is located at the intersection of the first connecting body 131 and the second connecting body 133, and faces away from the splicing main body 135. The corner transition portion 137 extends along a third direction 105 perpendicular to both the first direction 101 and the second direction 103, and both ends of the corner transition portion 137 protrude out of the end surface of the splice 130. When the first section bar 110 and the second section bar 120 are spliced by the splicing member 130, the frame is a complete and smooth frame when viewed from the outside.

Optionally, in order to improve the security of the corner position of the frame structure after the splicing, the side surface of the corner transition portion 137 is an arc surface, so that the smooth transition between the corner transition portion and the first section bar 110 and the second section bar 120 is realized, the product has no sharp corner, the sharp corner of the frame product is prevented, and the use security of the product is improved while the product is attractive.

Optionally, the splicing element 130 is integrally formed, that is, the first connecting body 131, the second connecting body 133, the splicing main body 135 and the corner transition portion 137 are integrally formed, optionally, the splicing element is integrally formed by injection molding, which is beneficial to the convenience of production and manufacture.

Further, in order to increase the strength of the frame after the splicing, the splicing position is not easily deformed. Optionally, as shown in fig. 10, the splicing element 130 is provided with a rib 139.

Specifically, as shown in fig. 10, the first connecting body 131 includes a first outer side surface 1317 facing away from the splice body 135, the second connecting body 133 includes a second outer side surface 1337 facing away from the splice body 135, and the splice body 135 includes a first mating surface 1355, a second mating surface 1356, and a third mating surface 1357 disposed adjacently.

The first mating surface 1355 is a side of the splice body 135 adjacent to the first connecting body 131 and the second connecting body 133, the second mating surface 1356 is opposite to the first outer side 1317 of the first connecting body 131, and the third mating surface 1357 is opposite to the second outer side 1337 of the second connecting body 133.

Optionally, at least one of the first outer side surface 1317, the second outer side surface 1337, the first mating surface 1355, the second mating surface 1356 and the third mating surface 1357 is provided with a rib 139. At least one of the surfaces is provided with a rib 139 on a part or all of the surface.

In this embodiment, the ribs 139 are disposed on all of the first outer side surface 1317, the second outer side surface 1337, the first mating surface 1355, the second mating surface 1356 and the third mating surface 1357. The convex ribs 139 on the first outer side surface 1317, the first mating surface 1355 corresponding to the first splicing portion 1351 and the second mating surface 1356 extend along the first direction 101; the second exterior side 1337, the first mating surface 1355 corresponding to the second splice portion 1353, and the bead 139 on the third mating surface 1357 all extend along the second direction 103.

Further, the splicing element 130 is tightly fitted with the first section bar 110 and the second section bar 120 during splicing, so as to meet the strength requirement of assembly.

Specifically, when the splicing member 130 is assembled with the first profile 110, the first connecting body 131 and the first splicing portion 1351 are inserted into the first inner cavity 111 of the first profile 110. And the inner surface of the first inner cavity 111 of the first profile 110 will wear away a portion of the ribs 139 on the first connecting body 131 and the first splicing portion 1351, so that the ribs 139 on the first outer side surface 1317 of the first connecting body 131, the first mating surface 1355 of the first splicing portion 1351 and the second mating surface 1356 of the first splicing portion 1351 are tightly fitted with the inner surface of the first inner cavity 111 of the first profile 110.

Similarly, when the splice 130 is assembled with the second profile 120, the second connector 133 and the second splice 1353 are inserted into the second cavity 121 of the second profile 120, and the inner surface of the second cavity 121 of the second profile 120 will wear away a portion of the ribs 139 on the second connector 133 and the second splice 1353, so that the second outer side 1337 of the second connector 133, the first mating surface 1355 of the second splice 1353, and the ribs 139 on the third mating surface 1357 are tightly fitted with the inner surface of the second cavity 121 of the second profile 120.

The strength requirement of the spliced frame body splicing structure is met through the tight fit between the convex ribs 139 and the inner surfaces of the first inner cavity 111 and the second inner cavity 121. On the basis of ensuring the structural strength of the frame splicing structure 100, the contact area between the splicing element 130 and the first section bar 110 and the second section bar 120 is reduced, so that the friction force is reduced, the acting force required during splicing is saved, and smooth installation is facilitated.

Optionally, the splicing member 130 is made of plastic, is easy to produce, and has a certain plastic deformation capability.

The embodiment of the utility model provides a framework mosaic structure 100 utilizes first elasticity knot 1313 and second elasticity knot 1333 atress can take place elastic deformation's characteristic in splice 130. During the assembly process, the first protrusion 13133 of the first elastic buckle 1313 presses the first elastic body 13131 to be elastically deformed. When the first protrusion 13133 is engaged with the first engaging hole 112 of the first section bar 110, the extrusion force disappears, and the first elastic buckle 1313 returns to the original state; the second protrusion 13333 of the second elastic buckle 1333 presses the second elastic body 13331 to be elastically deformed. After the second protrusion 13333 is engaged with the second engaging hole 123 of the second profile 120, the pressing force disappears, and the second elastic buckle 1333 returns to the original state. Therefore, clamping assembly is completed, the installation efficiency of the frame splicing structure 100 is improved on the premise of not using a screw connector or glue, and the attractiveness of products is improved.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art will understand that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention in its corresponding aspects.

Claims (10)

1. A frame splicing structure, comprising:

the first section bar is provided with a first inner cavity, and the end part of the first section bar is provided with a first clamping hole;

the second section bar is provided with a second inner cavity, and the end part of the second section bar is provided with a second clamping hole; and

the splicing piece comprises a first connecting body and a second connecting body which are fixedly connected, the first connecting body extends along a first direction, the second connecting body extends along a second direction, the first connecting body comprises a first elastic buckle, and the second connecting body comprises a second elastic buckle;

the first connecting body is embedded in the first inner cavity, the first elastic buckle is connected with the first clamping hole in a clamped mode, the second connecting body is embedded in the second inner cavity, and the second elastic buckle is connected with the second clamping hole in a clamped mode.

2. The frame splicing structure according to claim 1, wherein the first connecting body further comprises a first connecting body, one end of the first elastic buckle is connected with the first connecting body, the other end of the first elastic buckle extends in a direction opposite to the first direction, and a first elastic gap is formed between the other end of the first elastic buckle and the first connecting body;

the second connector further comprises a second connecting body, one end of the second elastic buckle is connected with the second connecting body, the other end of the second elastic buckle extends in the direction opposite to the second direction, and a second elastic gap is formed between the other end of the second elastic buckle and the second connecting body.

3. The frame splicing structure according to claim 2, wherein the first connecting body comprises a first embedding portion, a first clamping portion and a first matching portion which are connected in sequence, the first clamping portion is recessed relative to the first embedding portion and the first matching portion, the first elastic buckle is connected with the first embedding portion and extends towards the first matching portion, and a first elastic gap is formed between the first elastic buckle and the first clamping portion and between the first elastic buckle and the first matching portion;

the body is connected to the second inlays and establishes portion, second joint portion and second cooperation portion including the second that connects gradually, second joint portion for the second inlay establish the portion with second cooperation portion is sunken, second elasticity detain with the second inlays and establishes the portion and connect and move towards second cooperation portion extends, second elasticity detain with second joint portion with have between the second cooperation portion second elastic gap.

4. The frame splicing structure of claim 2, wherein the first elastic buckle is located on one side of the first connecting body close to the second connecting body, and the second elastic buckle is located on one side of the second connecting body close to the first connecting body.

5. The frame splicing structure according to claim 1, wherein the first elastic buckle comprises a first elastic body and a first protrusion protruding from the first elastic body, the first elastic body tends to deform elastically under the action of an external force, and when the first connecting body is connected to the first profile, the first protrusion is engaged with the first engaging hole;

the second elastic buckle comprises a second elastic body and a second convex block convexly arranged on the second elastic body, the second elastic body has the tendency of elastic deformation under the action of external force, and when the second connecting body is connected to the second section bar, the second convex block is clamped in the second clamping hole.

6. The frame splicing structure of claim 5, wherein the first protrusion comprises a first guiding inclined surface, and an included angle between the first guiding inclined surface and the first direction is an obtuse angle;

the second lug includes second direction inclined plane, the second direction inclined plane with the contained angle between the second direction is the obtuse angle.

7. The frame splicing structure of any one of claims 1 to 6, wherein the splicing member further comprises a splicing main body, and the splicing main body is connected with the first connecting body and the second connecting body at the same time and is positioned at the same side of the first connecting body and the second connecting body;

the splicing main body comprises a first splicing part and a second splicing part, the first splicing part corresponds to the first connector and extends along the first direction, and the second splicing part corresponds to the second connector and extends along the second direction.

8. The frame splicing structure of claim 7, wherein the first connecting body comprises a first outer side facing away from the splicing main body, and the second connecting body comprises a second outer side facing away from the splicing main body;

the splicing main body comprises a first matching surface, a second matching surface and a third matching surface which are arranged adjacently, the first matching surface is one side surface of the splicing main body close to the first connecting body and the second connecting body, the second matching surface and the first outer side surface are arranged oppositely, and the third matching surface and the second outer side surface are arranged oppositely;

the first outer side surface, the second outer side surface, the first matching surface, the second matching surface and the third matching surface are all provided with convex ribs;

the first connecting body and the splicing main body are tightly matched with the first section bar through the convex rib;

the second connector with the concatenation main part passes through protruding muscle with the second section bar tight fit.

9. The frame splicing structure of claim 7, wherein a corner transition part is arranged at the intersection of the first connecting body and the second connecting body and on the side facing away from the splicing main body;

the first connector, the second connector, the splicing main body and the corner transition part are integrally formed.

10. The frame splicing structure of claim 7, wherein a side of the first splicing part facing away from the first connecting body is provided with a first guide part matched with the first profile, and a side of the second splicing part facing away from the second connecting body is provided with a second guide part matched with the second profile.

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