CN114893058B - Support structure and manufacturing method thereof - Google Patents

Abstract

The invention provides a supporting structure and a manufacturing method thereof, wherein the supporting structure comprises a cover unit, the cover unit comprises a plurality of splice bodies, and the splice bodies are spliced along a shape path of the supporting structure; and the inner core unit is filled in the spliced body along the shape path of the supporting structure. The cover units have shaping capability and are formed by splicing the spliced bodies along the shape path of the supporting structure, wherein the inner core units can be inflatable columns and are filled in the spliced bodies along the shape path of the supporting structure to form the supporting structure. Utilize the design ability of envelope unit, and will the unit parcel of envelope in the inner core unit is outside, has solved the difficult problem because of the design of flexible inner core unit and the poor with the holding ability, guarantees bearing structure structural stability, support and design ability, avoids bearing structure is scattered the frame, and influences availability factor.

Description

Support structure and manufacturing method thereof

Technical Field

The invention relates to the technical field of supporting structures, in particular to a supporting structure applied to a tent and a manufacturing method thereof.

Background

Tent generally comprises a support structure made of rigid material and a tent cloth, wherein when in use, after a plurality of metal long pipes and joints of the support structure are assembled into a preset three-dimensional shape, the tent cloth is covered on the top of the assembled support structure so as to provide sun and rain shading effects. Because tents are primarily intended for temporary use only, there are problems in the transportation thereof and the time for installing them in such a situation, and in order to compensate for these disadvantages, there has been developed an inflatable support structure which utilizes inflation to form a support structure capable of supporting a tent cloth, and which can be stored by deflation folding, facilitating transportation and improving the assembly efficiency of the tent.

At present, an inflatable supporting structure is built by an inflatable column, and an inflation valve is arranged on the inflatable column to perform inflation and deflation. The inflatable column is made of flexible materials with good air tightness, and although the flexible materials are light so as to be convenient to store and transport, the inflated inflatable column is poor in supporting and shaping effects, and tent scattering and other phenomena are easy to occur, so that the service condition of the inflatable tent is affected.

Disclosure of Invention

The present invention is directed to a support structure and a method for manufacturing the same that can effectively improve the support and shaping capabilities of the support structure. The aim of the invention can be achieved by the following technical scheme:

according to one object of the present invention, there is provided a support structure comprising:

the cover unit comprises a plurality of splice bodies, and the splice bodies are spliced along the shape path of the supporting structure;

and the inner core unit is filled in the spliced body along the shape path of the supporting structure.

As a preferred embodiment, the splice body has an opening side that can be closed, so that when a plurality of splice bodies are spliced, the opening sides of the plurality of splice bodies are continuously connected, so that the core unit is placed inside the splice body through the continuously connected opening sides.

As a preferred embodiment, the splice body includes two cut pieces, the cut pieces include a first splice line, a second splice line, a first seal line and a second seal line, the first splice line, the first seal line, the second splice line and the second seal line are sequentially connected and define an outer contour of the cut pieces, the first seal lines of the two cut pieces are connected, and a closable opening side is formed between the second seal lines, so that the inner core unit is packaged between the two cut pieces.

In a preferred embodiment, in each of the splice bodies, the first splice lines of the two cut pieces are opposite to each other, and the second splice lines are opposite to each other, so that the adjacent two splice bodies are spliced by the first splice lines and the second splice lines.

As a preferred embodiment, the shape path of the support structure has a first support path, a second support path and a third support path, which are respectively crossed and bent, and are integrally connected at the top of the support structure in a staggered manner.

As a preferred embodiment, the first supporting path includes a first bottom edge portion, a first outer edge portion and a first inner edge portion, the first outer edge portion and the first inner edge portion intersecting and being curvedly connected to both ends of the first bottom edge portion;

the second supporting path comprises a second bottom edge part, a second outer edge part and a second inner edge part, wherein the second outer edge part and the second inner edge part are crossed and connected with two ends of the second bottom edge part in a bending way;

the third supporting path comprises a third bottom edge part, a third outer edge part and a third inner edge part, wherein the third outer edge part and the third inner edge part are crossed and connected with two ends of the third bottom edge part in a bending way;

the first outer edge part and the second inner edge part are integrally connected and form a first intersection, the first inner edge part and the third outer edge part are integrally connected and form a second intersection, the second outer edge part and the third inner edge part are integrally connected and form a third intersection, and the first intersection, the second intersection and the third intersection are arranged from top to bottom.

According to another object of the present invention, there is also provided a method of manufacturing a support structure, comprising the steps of:

s100, providing a cover unit and an inner core unit, wherein the cover unit comprises a plurality of splice bodies;

and S200, splicing the plurality of spliced bodies along the shape path of the supporting structure, and filling the inner core units into the spliced bodies along the shape path of the supporting structure.

As a preferred embodiment, the splice body has an opening side capable of being closed, and the step S200 further includes:

s210, splicing a plurality of spliced bodies in a mode that the opening sides are continuously communicated;

s220, placing the inner core unit into the spliced body through the opening side, and closing the opening side.

As a preferred embodiment, the splice body includes two cutting pieces, the cutting pieces include a first splicing line, a second splicing line, a first sealing line and a second sealing line, the first splicing line, the first sealing line, the second splicing line and the second sealing line are sequentially connected, and define an outer contour of the cutting piece, and further the step S210 includes:

aligning and connecting the first sealing lines of the two cutting blades so as to form an opening side capable of being closed between the second sealing lines of the two cutting blades;

two adjacent splice bodies are spliced through a first splice line and a second splice line.

As a preferred embodiment, the step S220 includes:

placing the inner core unit inside the two cutting pieces through the opening side:

and closing the second sealing lines of the two cutting pieces so that the inner core unit is packaged between the two cutting pieces.

Compared with the prior art, the technical scheme has the following advantages:

the cover unit has setting capability and is formed by splicing the splicing bodies along the shape path of the supporting structure, namely the cover unit defines the shape of the supporting structure. The inner core unit can be an inflatable column and is filled inside the spliced body along the shape path of the supporting structure so as to form the supporting structure. Utilize the design ability of envelope unit, and will the unit parcel of envelope in the inner core unit is outside, has solved the difficult problem because of the design of flexible inner core unit and the poor with the holding ability, guarantees bearing structure structural stability, support and design ability, avoids bearing structure is scattered the frame, and influences availability factor. In addition, the cover unit is formed by splicing a plurality of spliced bodies, so that the spliced positions of the spliced bodies can bind the inner core unit, the inner core unit is filled along with the shape path defined by the cover unit, the support structure with the corresponding shape is convenient to form, and the forming is convenient and quick. And through the inner core unit is filled and is deflated, the cover unit is not required to be disassembled, the storage can be realized, and the recycling is convenient.

The invention is further illustrated by the following examples in conjunction with the accompanying drawings.

Drawings

FIG. 1 is a schematic view of a first embodiment of a support structure according to the present invention;

FIG. 2 is a schematic view of a second embodiment of a support structure according to the present invention;

FIG. 3 is a schematic view of a third support path according to the present invention;

FIG. 4 is an exploded view of a cut sheet of the third support path of the present invention;

fig. 5 is an exploded view of a third outer edge portion of the cut sheet according to the present invention.

Detailed Description

The following description is presented to enable one of ordinary skill in the art to make and use the invention. The preferred embodiments in the following description are by way of example only and other obvious variations will occur to those skilled in the art. The basic principles of the invention defined in the following description may be applied to other embodiments, variations, modifications, equivalents, and other technical solutions without departing from the spirit and scope of the invention.

As shown in fig. 1, the support structure includes:

a cover unit 100, wherein the cover unit 100 includes a plurality of splice bodies 110, and the plurality of splice bodies 110 are spliced along a shape path 300 of the support structure;

the core unit 200, the core unit 200 is filled inside the splice body 110 along the shape path 300 of the support structure.

The cover unit 100 has a setting capability and is formed by the splice body 110 along the shape path 300 of the support structure, i.e. the cover unit 100 defines the shape of the support structure. Wherein the core unit 200 may be an inflatable column and is filled inside the spliced body 110 along a shape path 300 of the support structure to form the support structure. The shaping capability of the cover unit 100 is utilized, and the cover unit 100 is wrapped outside the core unit 200, so that the difficult problem of poor shaping and supporting capability of the flexible core unit 200 is solved, the structural stability, supporting and shaping capability of the supporting structure are ensured, and the influence on the service efficiency caused by the fact that the supporting structure is scattered is avoided. In addition, the cover unit 100 is formed by splicing a plurality of the splice bodies 110, so that the splice parts of the splice bodies 110 can bind the core unit 200, and the core unit 200 is filled along with the shape path 300 defined by the cover unit 100, so that the support structure with the corresponding shape is formed, and the forming is convenient and quick.

As shown in fig. 1, the splice body 110 has an opening side 1100 that can be closed, so that when a plurality of splice bodies 110 are spliced, the opening sides 1100 of the splice bodies 110 are continuously connected, so that the core unit 200 is placed inside the splice body 110 through the continuously connected opening sides 1100.

When the splice body 110 is spliced, the open sides 1100 are arranged on the same side, so that the open sides 1100 of the splice bodies 110 are continuously communicated, the inner core unit 200 is placed inside the splice body 110 through the continuously communicated open sides 1100, and then the open sides 1100 are closed, so that the inner core unit 200 can be packaged inside each splice body 110.

When it should be noted that the splicing of the splicing body 110 and the placement of the core unit 200 may be performed simultaneously, for example, after the core unit 200 is placed inside the current splicing body 110, the opening side 1100 of the current splicing body 110 is closed, and at the same time, another splicing body 110 is spliced on the current splicing body 110, and the core unit 200 is placed inside another splicing body 110, and then the opening side 1100 of the other splicing body 110 is closed, so that the forming of the support structure is completed.

Of course, the inner core units 200 may be arranged after the plurality of the spliced bodies 110 are spliced along the shape path 300 of the supporting structure, the spliced open sides 1100 of the spliced bodies 110 remain, at this time, the inner core units 200 are arranged on the spliced bodies 110 one by one through the open sides 1100, and finally the open sides 1100 of the spliced bodies 110 are closed, so as to complete the forming of the supporting structure.

As shown in fig. 1 and 2, the splice body 110 includes two cut pieces 111, the cut pieces 111 include a first splice line 111a, a second splice line 111b, a first seal line 111d, and a second seal line 111c, the first splice line 111a, the first seal line 111d, the second splice line 111b, and the second seal line 111c are sequentially connected and define an outer contour of the cut pieces 111, the first seal lines 111d of the two cut pieces 111 are connected, and a closable opening side 1100 is formed between the second seal lines 111c, so that the core unit 200 is encapsulated between the two cut pieces 111.

In each of the splice bodies 110, the two cut pieces 111 are connected in such a manner that the outer contours thereof are substantially aligned, wherein the first seal lines 111d of the two cut pieces 111 are connected, the second seal lines 111c of the two cut pieces 111 form an opening side 1100 capable of being closed therebetween, the first splice lines 111a of the two cut pieces 111 are opposed for splicing the other splice body 110, and the second splice lines 111b of the two cut pieces 111 are opposed for splicing the other splice body 110.

Specifically, the spliced body 110 is tubular, openings are formed between the first spliced lines 111a opposite to the two cut pieces 111 and between the second spliced lines 111b opposite to each other for the core unit 200 to pass out, and another spliced body 110 is connected at the opening of the spliced body 110, referring to fig. 1. More specifically, the two adjacent spliced bodies 110 are spliced by the first spliced line 111a and the second spliced line 111b, that is, the first spliced line 111a of the current spliced body 110 is connected with the second spliced line 111b of the other spliced body 110, so as to achieve splicing of the two adjacent spliced bodies 110.

The cutting sheet 111 may be cut from a composite plastic material, the first seal lines 111d and the second seal lines 111c of the two cutting sheets 111 may be connected by stitching or bonding, and the first and second splice lines 111a and 111b of the two adjacent splice bodies 110 may be connected by stitching or bonding.

The core unit 200 may be an integral ring structure, which can be continuously filled in the cover unit 100, and of course, the core unit 200 may also be a multi-stage split structure, and sequentially disposed in the cover unit 100 end to end.

The shape of the cut sheet 111 of each of the splice bodies 110 may be different, and will be described in detail below by a clover-shaped support structure:

as shown in fig. 2, the shape path 300 of the support structure has a first support path 310, a second support path 320 and a third support path 330, and the first support path 310, the second support path 320 and the third support path 330 are respectively crossed and bent, and are integrally connected at the top of the support structure in a staggered manner. The first supporting path 310, the second supporting path 320 and the third supporting path 330 which are bent in a crossing manner are equivalent to three blades of clover, so that the supporting structure is approximately in an arched clover shape, even the whole supporting structure can be approximately in a spherical structure, and the supporting capability of the supporting structure is ensured, collapse is effectively prevented, and the stability of the structure is further improved because the first supporting path 310, the second supporting path 320 and the third supporting path 330 are bent in a crossing manner.

When the support structure is applied to a tent, a tent cloth is laid on the support structure to form a rest space inside surrounded by the first, second and third support paths 310, 320 and 330. Of course the support structure may also find application in its field, such as mosquito nets and the like.

With continued reference to fig. 2, the first supporting path 310 includes a first bottom edge 311, a first outer edge 312, and a first inner edge 313, and the first outer edge 312 and the first inner edge 313 intersect and are connected to both ends of the first bottom edge 311 in a bending manner;

the second supporting path 320 includes a second bottom edge 321, a second outer edge 322, and a second inner edge 323, the second outer edge 322 and the second inner edge 323 intersecting and being bent to connect to both ends of the second bottom edge 321;

the third supporting path 330 includes a third bottom edge 331, a third outer edge 332 and a third inner edge 333, the third outer edge 332 and the third inner edge 333 intersecting and being connected to both ends of the third bottom edge 331 in a bending manner;

the first outer edge 312 and the second inner edge 323 are integrally connected to form a first intersection 3001, the first inner edge 313 and the third outer edge 332 are integrally connected to form a second intersection 3002, the second outer edge 322 and the third inner edge 333 are integrally connected to form a third intersection 3003, and the first intersection 3001, the second intersection 3002 and the third intersection 3003 are arranged in a superimposed manner from top to bottom, so that the first support path 310, the second support path 320 and the third support path 330 are integrally formed and can be stably supported on the ground.

The shapes of the first supporting path 310, the second supporting path 320 and the third supporting path 330 are substantially the same, the arrangement of the cut pieces 111 may also be the same, for example, the third supporting path 330 is taken as an example, the arrangement of the cut pieces 111 of the third outer edge 332 and the third inner edge 333 is the same, and a corner 334 is formed between the third outer edge 332 and the third inner edge 333 and the third bottom edge 331, respectively, referring to fig. 3.

The cut pieces corresponding to the third bottom edge 331 are divided into a third bottom edge upper cut piece 331a and a third bottom edge lower cut piece 331b, the cut pieces corresponding to the corner 334 are divided into a corner upper cut piece 334a and a corner lower cut piece 334b, and the cut pieces corresponding to the third inner edge 333 are respectively a third right cut piece 333a and a third left cut piece 333b, referring to fig. 3 and 4.

The third left cutting piece 333b, the corner upper cutting piece 334a and the third bottom edge upper cutting piece 331a are sequentially spliced, the third right cutting piece 333a, the corner lower cutting piece 334b and the third bottom edge lower cutting piece 331b are sequentially spliced, wherein both sides of the corner upper cutting piece 334a are concave, the connecting side of the third bottom edge upper cutting piece 331a and the corner upper cutting piece 334a is concave, and the connecting side of the third left cutting piece 333b and the corner upper cutting piece 334a is convex. In addition, the two sides of the lower corner cutting piece 334b are protruded, the connecting side of the lower third bottom edge cutting piece 331b and the lower corner cutting piece 334b is protruded, and the connecting side of the right third cutting piece 333a and the lower corner cutting piece 334b is recessed, so as to form the structure shown in fig. 3.

Further, the third bottom edge upper cutting piece 331a and the third bottom edge lower cutting piece 331b are arc-shaped, so that the third bottom edge 331 is arc-shaped, and the supporting capability of the third supporting path 330 on the ground is improved.

With continued reference to fig. 4, the third bottom edge upper cutting blade 331a is provided with a plurality of right through holes for installing an inflation valve to inflate and deflate the core unit 200 encapsulated in the third bottom edge upper cutting blade 331a and the third bottom edge lower cutting blade 331 b.

In addition, the number of the splice bodies 110 corresponding to the third outer edge 332 and the third inner edge 333 may be plural, and the shape of the cut piece of each splice body 110 may be different, referring to fig. 2 and 5. Taking the third outer edge 332 as an example, the cutting piece of a certain spliced body 110 is divided into a left cutting piece 3331b and a right cutting piece 3331a, wherein the first splicing lines 111a and the second splicing lines 111b of the left cutting piece 3331b and the right cutting piece 3331a are all linear, the first sealing line 111d is concave, and the second sealing line 111c is convex, referring to fig. 5, so that the whole left cutting piece 3331b and the right cutting piece 3331a are arc-shaped, that is, the spliced body 110 formed by connecting is also arc-shaped. The width dimensions of each of the splice bodies 110 may be uniform, the length dimensions may be different, and the number of splice bodies 110 may be set according to design requirements.

In addition, the core unit 200 may be interposed from the concave line type first seal line 111d of the left cut piece 3331b and the right cut piece 3331a or from the convex line type second seal line 111 c.

In summary, the cover unit 100 has a setting capability, and is formed by splicing the splice body 110 along the shape path 300 of the supporting structure, that is, the cover unit 100 defines the shape of the supporting structure. Wherein the core unit 200 may be an inflatable column and is filled inside the spliced body 110 along a shape path 300 of the support structure to form the support structure. The shaping capability of the cover unit 100 is utilized, and the cover unit 100 is wrapped outside the core unit 200, so that the difficult problem of poor shaping and supporting capability of the flexible core unit 200 is solved, the structural stability, supporting and shaping capability of the supporting structure are ensured, and the influence on the service efficiency caused by the fact that the supporting structure is scattered is avoided. In addition, the cover unit 100 is formed by splicing a plurality of the splice bodies 110, so that the splice parts of the splice bodies 110 can bind the core unit 200, and the core unit 200 is filled along with the shape path 300 defined by the cover unit 100, so that the support structure with the corresponding shape is formed, and the forming is convenient and quick. And through the inflation and deflation of the inner core unit 200, the cover unit 100 can be stored without being disassembled, and the recycling is convenient.

As shown in fig. 1, the present invention further provides a method for manufacturing a support structure, including the following steps:

s100, providing a cover unit 100 and an inner core unit 200, wherein the cover unit 100 comprises a plurality of splice bodies 110;

and S200, splicing a plurality of the splicing bodies 110 along the shape path 300 of the supporting structure, and filling the inner core units 200 into the splicing bodies 110 along the shape path 300 of the supporting structure.

The cover unit 100 ensures the setting support capability of the support structure, and avoids the collapse of the support structure. The inner core unit 200 may be built in the spliced body 110, or may be built in the spliced body 110 while being spliced, so that the inner core unit 200 is plastic inside the cover unit 100 along with the shape path 300, thereby ensuring the supporting capability and the shaping capability of the supporting structure, and further improving the stability of the supporting structure. Meanwhile, the cover unit 100 is formed by splicing, so that the manufacturing efficiency is effectively improved.

The cover unit 100 is formed by splicing a plurality of splice bodies 110 along a shape path 300 of the supporting structure, and may have a clover shape as shown in fig. 2. The core unit 200 may be an inflatable column, and may be configured to be unfolded and stored by inflation and deflation, and the core unit 200 may be an integral ring structure, which may be continuously filled in the cover unit 100, or the core unit 200 may be a multi-stage split structure, and sequentially disposed in the cover unit 100 from end to end.

As shown in fig. 1, the splice body 110 has an opening side 1100 capable of being closed, and the step S200 further includes:

s210, splicing a plurality of splicing bodies 110 in a mode that the opening sides 1100 are continuously communicated;

s220, placing the core unit 200 into the splice body 110 through the opening side 1100, and closing the opening side 1100.

When the splice body 110 is spliced, the open sides 1100 are arranged on the same side, so that the open sides 1100 of the splice bodies 110 are continuously communicated, the inner core unit 200 is placed inside the splice body 110 through the continuously communicated open sides 1100, and then the open sides 1100 are closed, so that the inner core unit 200 can be packaged inside each splice body 110.

Specifically, the splice body 110 includes two cut pieces 111, the cut pieces 111 include a first splicing line 111a, a second splicing line 111b, a first sealing line 111d, and a second sealing line 111c, the first splicing line 111a, the first sealing line 111d, the second splicing line 111b, and the second sealing line 111c are sequentially connected, and define an outer contour of the cut pieces 111, and further the step S210 includes:

the first sealing lines 111d of the two cutting sheets 111 are aligned and connected, so that an opening side 1100 capable of being closed is formed between the second sealing lines 111c of the two cutting sheets 111;

two adjacent splice bodies 110 are spliced by a first splice line 111a and a second splice line 111 b.

Further, the step S220 includes:

the core unit 200 is placed inside the two cut pieces 111 through the opening side 1100:

the second seal lines 111c of the two cut pieces 111 are closed so that the core unit 200 is encapsulated between the two cut pieces 111.

The cutting sheet 111 may be cut from a composite plastic material, the first seal lines 111d and the second seal lines 111c of the two cutting sheets 111 may be connected by stitching or bonding, and the first and second splice lines 111a and 111b of the two adjacent splice bodies 110 may be connected by stitching or bonding.

The above-described embodiments are only for illustrating the technical spirit and features of the present invention, and it is intended to enable those skilled in the art to understand the content of the present invention and to implement it accordingly, and the scope of the present invention as defined by the present embodiments should not be limited only by the present embodiments, i.e. equivalent changes or modifications made in accordance with the spirit of the present invention will still fall within the scope of the present invention.

Claims (8)

1. A support structure, comprising:

a cover unit (100), wherein the cover unit (100) comprises a plurality of splice bodies (110), and the splice bodies (110) are spliced along a shape path (300) of the supporting structure;

-a core unit (200), the core unit (200) being filled inside the splice (110) along a shape path (300) of the support structure;

the shape path (300) of the support structure is provided with a first support path (310), a second support path (320) and a third support path (330), wherein the first support path (310), the second support path (320) and the third support path (330) are respectively crossed and bent, and are integrally connected with each other at the top of the support structure in a staggered manner;

the first supporting path (310) comprises a first bottom edge part (311), a first outer edge part (312) and a first inner edge part (313), wherein the first outer edge part (312) and the first inner edge part (313) are crossed and connected to two ends of the first bottom edge part (311) in a bending way;

the second supporting path (320) comprises a second bottom edge part (321), a second outer edge part (322) and a second inner edge part (323), wherein the second outer edge part (322) and the second inner edge part (323) are crossed and connected at two ends of the second bottom edge part (321) in a bending way;

the third supporting path (330) comprises a third bottom edge part (331), a third outer edge part (332) and a third inner edge part (333), wherein the third outer edge part (332) and the third inner edge part (333) are intersected and connected at two ends of the third bottom edge part (331) in a bending way;

the first outer edge (312) and the second inner edge (323) are integrally connected and form a first intersection (3001), the first inner edge (313) and the third outer edge (332) are integrally connected and form a second intersection (3002), the second outer edge (322) and the third inner edge (333) are integrally connected and form a third intersection (3003), and the first intersection (3001), the second intersection (3002) and the third intersection (3003) are arranged from top to bottom.

2. The support structure according to claim 1, wherein the splice body (110) has an open side (1100) that can be closed, so that when several splice bodies (110) are spliced, the open sides (1100) of the splice bodies (110) are continuously connected, so that the core unit (200) is placed inside the splice body (110) through the continuously connected open sides (1100).

3. The support structure according to claim 2, wherein the splice body (110) comprises two cut pieces (111), the cut pieces (111) comprising a first splice line (111 a), a second splice line (111 b), a first seal line (111 d) and a second seal line (111 c), the first splice line (111 a), the first seal line (111 d), the second splice line (111 b) and the second seal line (111 c) being connected in sequence and defining an outer contour of the cut pieces (111), the first seal lines (111 d) of the two cut pieces (111) being connected, and the second seal line (111 c) forming a closable opening side (1100) therebetween, such that the core unit (200) is encapsulated between the two cut pieces (111).

4. A support structure according to claim 3, wherein in each of said splice bodies (110), first splice lines (111 a) of two of said cut pieces (111) are opposed, and second splice lines (111 b) are opposed, such that adjacent two of said splice bodies (110) are spliced by the first splice lines (111 a) and the second splice lines (111 b).

5. A method of manufacturing a support structure as claimed in any one of claims 1 to 4, comprising the steps of:

s100, providing a cover unit (100) and an inner core unit (200), wherein the cover unit (100) comprises a plurality of splice bodies (110);

s200, splicing the plurality of splicing bodies (110) along the shape path (300) of the supporting structure, and filling the inner core units (200) into the splicing bodies (110) along the shape path (300) of the supporting structure.

6. The method of manufacturing a support structure according to claim 5, wherein the splice (110) has an open side (1100) that can be closed, and further wherein the step S200 comprises:

s210, splicing a plurality of splicing bodies (110) in a mode that the opening sides (1100) are continuously communicated;

s220, placing the inner core unit (200) into the spliced body (110) through the opening side (1100), and closing the opening side (1100).

7. The method of manufacturing a support structure according to claim 6, wherein the splice (110) comprises two cut pieces (111), the cut pieces (111) comprising a first splice line (111 a), a second splice line (111 b), a first seal line (111 d) and a second seal line (111 c), the first splice line (111 a), the first seal line (111 d), the second splice line (111 b) and the second seal line (111 c) being connected in sequence and defining an outer contour of the cut pieces (111), and the step S210 further comprises:

aligning and connecting the first sealing lines (111 d) of the two cutting sheets (111) so as to form an opening side (1100) capable of being closed between the second sealing lines (111 c) of the two cutting sheets (111);

two adjacent splice bodies (110) are spliced through a first splice line (111 a) and a second splice line (111 b).

8. The method of manufacturing a support structure according to claim 7, wherein the step S220 includes:

placing the core unit (200) inside the two cut pieces (111) through an opening side (1100):

and closing the second sealing line (111 c) of the two cutting sheets (111) so that the inner core unit (200) is packaged between the two cutting sheets (111).