KR20220053411A - Manufacturing method of masonry assembly recycling used PET bottle and masonry assembly manufactured by the same - Google Patents

Abstract

The present invention relates to a masonry assembly using recycled PET bottles. The masonry assembly comprises: penetrating members in surfaces and the other surfaces of which cut holes partially cut and having a plurality of cut pieces are formed, respectively, and which can be continuously connected in a longitudinal direction; and insertion members which form a right angle with the penetrating members by passing through the penetrating members through the cut holes, have a plurality of fitting holes into which the cut pieces are inserted, and can be continuously connected in a longitudinal direction. Therefore, the masonry assembly using recycled PET bottles have vertical and horizontal coupling means using intersecting penetration of PET bottles of which the bodies are cut, and can be used primarily to store water or beverages, and secondarily to construct various structures with various shapes and purposes such as the exterior and interior walls of a building, landscaping facilities, furniture, wall greening structures, flower pots, and greenhouses, depending on the intention of users and designers.

Description

A masonry assembly using a PET bottle and a manufacturing method thereof {Manufacturing method of masonry assembly recycling used PET bottle and masonry assembly manufactured by the same}

The present invention relates to a masonry assembly using a PET bottle and a method for manufacturing the same.

A PET bottle is a bottle molded by a biaxial stretching molding method using polyethylene terephthalate (PET) among polyester resins.

These PET bottles have high transparency and high strength and gas barrier properties, so they are used for storing various contents.

As the usage of PET bottles is increasing, recycling has become an important issue. Accordingly, various studies and practices have been carried out internationally to use plastic bottles as a building material to replace traditional bricks and to confine them in buildings.

Through previous studies, it was found that plastic bottles filled with sand, soil, fly ash, or various plastic wastes did not reach the level of concrete, but were stronger and lighter than conventional bricks. In addition, the unique flexibility of unbreakable plastic bottles can withstand unexpected and sudden shocks such as earthquakes. However, PET bottles were originally designed for the purpose of containers for beverages, and in order to connect them to each other and use them as a masonry assembly, they have been mainly used by means of tying them with strings, wrapping them with wire mesh, or bonding them with cement mortar.

Republic of Korea Patent Publication No. 10-2006-0056592 (2006.05.25.) Republic of Korea Patent Registration No. 10-0298024 (May 28, 2001)

The present invention provides a masonry assembly using a PET bottle and a method for manufacturing the same, which can be easily combined and disassembled by cross-linking adjacent PET bottles without using an adhesive means.

In the masonry assembly using a plastic bottle according to an embodiment of the present invention, a plurality of partial incisions are formed on one surface and the other surface, respectively, with incision holes having a plurality of incisions, a penetrating member that can be continuously connected along the longitudinal direction, and the incision hole A plurality of fitting holes through which the penetrating member is penetrated to form a right angle to the penetrating member are inserted, and an insertion member capable of being continuously connected in the longitudinal direction is included.

The penetrating member includes a penetrating body in which the cut-out hole is formed, a penetrating surplus part connected to the penetrating body by a fold line and folded based on the fold line so that the outer periphery is in contact with the penetrating body, and the penetrating surplus part and the It may include a binding means for bonding the through body to maintain the folded state of the penetrating excess.

In order to form the fold line at a predetermined position spaced apart from the lower surface of the penetrating member upward, it is cut along the outer periphery except for at least a portion, and is divided into the penetrating body and the penetrating excess based on the fold line, The lower end of the through-body may be opened by folding the through-over portion.

The cut-out hole may be formed by cutting the penetrating member in a "卍" shape.

The insertion member includes an insertion body in which the fitting hole is formed, an insertion surplus or an insertion surplus that is connected to the insertion body by a fold line and is folded based on the fold line so that the outer periphery is in contact with the insertion body and the insertion surplus By joining the insertion body may include a binding means for maintaining the folded state of the insertion surplus part.

In order to form the fold line at a predetermined position spaced apart from the lower surface of the insert member upward, it is cut along the outer periphery except for at least a portion, and is divided into the insert body and the insertion surplus based on the fold line, The lower end of the insertion body may be opened by folding of the insertion surplus part.

A plurality of the fitting holes are formed at intervals along the circumferential direction around the outer circumference of the inserting member, and the fitting holes are formed in a first row and a second row along the longitudinal direction of the inserting member, and the fitting holes in the first row The fitting holes of the second row and the second row may be alternately positioned, and a portion between the first row and the second row may be positioned inside the penetrating member.

A through hole connecting the inside of the penetrating member and the inside of the inserting member may be formed in a portion between the first row and the second row on one surface and the other surface of the insert member.

The masonry assembly using the plastic bottle may further include a first reinforcing material inserted into one end of the penetrating member and exposed to the other end of the penetrating member through the through hole, and a second reinforcing material penetrating the inside of the inserting member. there is.

The masonry assembly using the PET bottle may further include a filling material located inside the penetrating member and the inserting member.

In the method for manufacturing a masonry assembly using a plastic bottle according to an embodiment of the present invention, the upper end surface and the other surface of the plastic bottle are cut in a "卍" shape, respectively, to form an incision hole having an incision, and the outer perimeter of the lower end is cut off but a part is left The step of forming a penetrating member having a fold line by placing it, the step of folding the surplus through the penetrating member based on the fold line and combining it with the penetrating body by a binding means, cutting at intervals along the outer periphery of the upper end of the plastic bottle to make a fitting hole Forming and cutting the outer perimeter of the lower end but leaving a portion to form an insert having a fold line, folding the insertion surplus of the insert member based on the fold line and combining it with the insert body with a fold binding means, the step of and penetrating the through body through the cut-out hole and inserting the cut-out piece into the insertion member through the fitting hole.

In the step of forming the insert member, the upper end of the PET bottle may be cut to form a through hole.

The method for manufacturing a masonry assembly using the plastic bottle may further include inserting a first reinforcing material into the penetrating member, and inserting a second reinforcing material into the inserting member.

The method for manufacturing a masonry assembly using the PET bottle may further include injecting a filling material into the penetrating member and the inserting member.

According to an embodiment of the present invention, the masonry assembly recycled plastic bottles are vertical and horizontal coupling means formed through the cross-penetration of the processed plastic bottles by cutting the body, and the lifespan as a primary use for storing water or beverages has ended. The recycled masonry assembly is a secondary use that can build various structures with various shapes and purposes, such as exterior walls, interior walls, landscaping facilities, furniture, wall greening structures, flowerpots, and greenhouses, according to the intentions of users and designers. can be utilized. Therefore, it has a useful effect in creating design products in various fields such as architecture, interior, landscaping, and furniture production.

1 is a perspective view showing a masonry assembly using a PET bottle according to an embodiment of the present invention.
Figure 2 is a perspective view showing the penetrating member of Figure 1;
Figure 3 is a view showing the penetrating member of Figure 2;
Figure 4 is a perspective view showing the insertion member of Figure 1;
Figure 5 is a view showing the insertion member of Figure 4;
6 to 10 are schematic views showing the coupling state of the penetrating member and the insertion member.
11 is a schematic view showing a state in which the reinforcing material is coupled to the penetrating member and the insertion member;
Fig. 12 is a front view of Fig. 1;
13 and 14 are schematic views showing the coupling state of the first masonry assembly and the second masonry assembly.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily carry out the present invention. However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein. Throughout the specification, like reference numerals are assigned to similar parts.

Then, a masonry assembly using a PET bottle according to an embodiment of the present invention will be described with reference to FIGS. 1 to 14 .

1 is a perspective view showing a masonry assembly using a plastic bottle according to an embodiment of the present invention, FIG. 2 is a perspective view showing the penetrating member of FIG. 1, FIG. 3 is a view showing the penetrating member of FIG. 2, FIG. 4 is 1 is a perspective view showing the inserting member of FIG. 1 , FIG. 5 is a view showing the inserting member of FIG. 4 , FIGS. 6 to 10 are schematic views showing the coupling state of the penetrating member and the inserting member, and FIG. 11 is the penetrating member and the inserting member It is a schematic view showing a state in which the reinforcement is coupled to the , Fig. 12 is a front view of Fig. 1 , and Figs. 13 and 14 are schematic views showing the state in which the first masonry assembly and the second masonry assembly are combined.

First, referring to FIG. 1 , the masonry assembly 100 using a plastic bottle according to this embodiment includes a penetrating member 10 and an insertion member 20, and a plurality of plastic bottles are vertically and horizontally communicated with each other. To connect, it is possible to insert sawdust, sand, soil, fly ash, or various plastic waste inside, and to insert a tension member (reinforcing material) such as a rope or reinforcing bar. In addition, the two plastic bottles are crossed and strongly coupled without using an adhesive means to facilitate bonding and disassembly. Use only cutting means, but process it so that there is no wasted part so that no waste is generated during the manufacturing process. The masonry assembly 100 using a PET bottle according to the present embodiment may further include a first reinforcing material 30a, a second reinforcing material 30b, and a filling material 40 .

The PET bottle forming the penetrating member 10 and the inserting member 20 may be made of polyethylene terephthalate (PET) or the like. The PET bottle may have a capacity of 2L. The PET bottle may have a vertical length of 320 mm and a width of 85 mm in the front and rear, left and right directions, respectively. The material and specifications of PET bottles may be changed in various ways depending on the PET bottles to be collected.

The insertion member 20 penetrates the penetrating member 10 while forming a right angle with the penetrating member 10 . The penetrating member 10 may be continuously connected along its longitudinal direction. The insertion member 20 may also be continuously connected along its longitudinal direction.

The first reinforcing member 30a passes through the continuously connected penetrating members 10 in the longitudinal direction and receives a tensile load acting on the continuously connected penetrating members 10 while coupling the penetrating members 10 . Both ends of the first reinforcing member 30a are exposed to the outside of the one-side penetrating member 10 and the other-side penetrating member 10n and are bound. The first reinforcing member 30a penetrates the insertion member 20 penetrating the penetrating member 10 .

The second reinforcing member 30b passes through the insertion member 20 to be continuously connected in the longitudinal direction and receives a tensile load acting on the continuously connected insertion member 20 while coupling the insertion members 20 . Both ends of the second reinforcing member 30b are exposed and bound to the outside of the one side insertion member 20 and the other side insertion member 20n.

The first reinforcing material 30a and the second reinforcing material 30b form a right angle. The first reinforcing material 30a and the second reinforcing material 30b may include any one selected from a wire, a rope, and a deformed reinforcing bar.

The filling material 40 is accommodated in the penetrating member 10 and the inserting member 20 . The filling material 40 may include any one selected from soil, sand, sawdust, mortar, and fly ash. The filling material 40 fills the inside of the penetrating member 10 and the inserting member 20 to form the masonry assembly into a strong and functional structure. However, the filler 40 may be omitted.

2 and 3, the penetrating member 10 is partially cut out so that cut-out holes 111 having a plurality of cut-off pieces 111a are formed in the front and back portions, respectively. The penetrating member 10 is a penetrating body 11 in which a cut-out hole 111 is formed, a penetrating surplus portion 13 connected to the penetrating body 11 by a fold line 12, and a fold based on the fold line 12. It includes a binding means 14 for bonding the through-surplus portion 13 and the through-body 11 .

The cut-out hole 111 is formed by cutting the through body 11 in a "卍" shape. Four cut pieces 111a are respectively formed on the front and rear surfaces of the through body 11 by the cut-out holes 111 in the "卍" shape.

In the penetrating member 10, the front, left and rear surfaces are entirely cut at positions spaced apart 13L by a predetermined length from the lower surface to the upper surface, and the right surface is not cut. A fold line 12 is formed on the uncut right side portion. Based on the fold line 12 , the penetrating member 10 is divided into a penetrating body 11 and a penetrating excess 13 . The penetrating surplus portion 13 is folded based on the fold line 12 so that the right side thereof is in contact with the right side of the through body 11 .

The binding means 14 is made of a wire, a cable tie, and the like. The binding means 14 penetrates and binds the penetrating body 11 and the penetrating excess 13 in the folded state. Through binding of the binding means 14, the penetrating surplus 13 maintains the folded state.

The lower portion of the penetrating body 11 is maintained in an open state due to the folding of the penetrating surplus part 13 . Accordingly, when the penetrating member 10 is continuously connected in the longitudinal direction, the upper side of the penetrating body 11 of the second penetrating member 10 is about 1/3 inward through the open lower part of the penetrating body of the first penetrating member 10 . connected when inserted.

Referring further to FIGS. 4 and 5 , fitting holes 211 are formed in the front, rear, left and right sides of the insert member 20 in the circumferential direction, respectively. The insertion member 20 is an insertion body 21 having a fitting hole 211 formed therein, is connected to the insertion body 21 by a folding line 22 , and is an insertion surplus that can be folded based on the folding line 22 . (23) and a binding means (24) for bonding the insertion surplus part (23) and the insertion body (21).

The fitting hole 211 is formed of a first row fitting hole 211a and a second row fitting hole 211b at intervals in the vertical direction from each side (front, rear, left and right side) of the insertion body 21 . . Here, the first row fitting hole 211a and the second row fitting hole 211b are alternately positioned. That is, based on the imaginary center line 20C formed in the center along the longitudinal direction of the insertion member 20 on each side, the first row fitting hole 211a is on the left side, and the second row fitting hole 211b is on the right side. is formed Here, the gap 211L between the first row fitting hole 211a and the second row fitting hole 211b is equal to the thickness 10T between the front and rear surfaces of the penetrating member 10 .

And through-holes 212 are formed in a portion between the first row fitting hole 211a and the second row fitting hole 211b formed on the front and back surfaces of the insertion body 21, respectively. The through hole 212 is formed by cutting the insertion body 21 in a “+” shape. As the first reinforcing material 30a inserted into the penetrating member 10 penetrates the cut-out portion in a “+” shape, the cut-out portion is folded to form a through-hole 212 .

In the insertion member 20, the front, back, and right sides of the insertion member 20 are entirely incised at positions spaced apart (23L) by a predetermined length in the direction from the lower surface to the upper surface, and the left surface is not cut. A fold line 22 is formed on the uncut left side portion. Based on the fold line 22 , the insertion member 20 is divided into an insertion body 21 and an insertion surplus 23 . The insertion surplus 23 is folded based on the fold line 22 so that the left side is in contact with the left side of the insertion body 21 .

The binding means 24 is made of a wire, a cable tie, and the like. The binding means 24 penetrates and binds the insertion body 21 and the insertion surplus part 23 in a state in which the insertion surplus part 23 is folded. By the binding of the binding means 24, the insertion surplus 23 maintains the folded state.

The lower portion of the insertion body 21 maintains an open state by folding of the insertion surplus part 23 . Accordingly, when the insertion member 20 is continuously connected in the longitudinal direction, the upper side of the insertion body 21 of the second insertion member 20 is about 1/3 inside through the open lower portion of the insertion body of the first insertion member 20 connected when inserted.

A block unit assembly is formed by combining the penetrating member 10 and the insertion member 20 made of a PET bottle, and since the plastic bottle is cut without cutting, waste or by-products are not generated during the manufacturing process of the masonry assembly. In addition, by filling the inside of the penetrating member 10 and the inserting member 20 with an inorganic material, a manufacturing by-product, etc., it may have strength enhancement and various functions according to the characteristics of the filling material.

Accordingly, the opposite side of the surface of the plastic bottle body on which the penetrating member 10 is to be formed is cut in a “卍” shape, and the incision is folded out to form a structure in which other plastic bottles (insertion members) can cross and penetrate. Fold out to make 8 wings, and 8 fitting holes are formed in the body surface of the PET bottle to form the insertion member 20, and while inserting it into the penetrating member 10, the two plastic bottles cross each other while fitting the cut piece into the fitting hole. to be combined. The lower ends of the two plastic bottles are cut so that the bottlenecks of other plastic bottles are inserted inside the open place so that they can be connected continuously so that the inside is connected while being combined in the vertical and horizontal directions. It can penetrate and fill the inside with various filling materials.

A method of manufacturing a masonry assembly formed by combining the penetrating member 10 and the inserting member 20 will be described with further reference to FIGS. 6 to 10 .

6 shows the separation state of the penetrating member and the inserting member, FIG. 7 shows the state in which the cutout of the penetrating member is folded and the cutout hole is opened, and FIG. 8 shows the state in which the inserting member is coupled to the penetrating member, 9 shows a state in which the penetrating member to which the insert member is coupled is stacked, and FIG. 10 shows a state in which the penetrating member to which the insert member is coupled is stacked.

The masonry assembly manufacturing method includes the steps of forming a penetrating member (S10), joining the through body of the penetrating member and the penetrating excess (S20), forming the inserting member (S30), and joining the insert body and the inserting excess of the inserting member ( S40), a step of passing the insertion member through the penetrating member (S50) and the step of inserting the cut piece into the fitting hole (S60). The method for manufacturing a masonry assembly according to the present embodiment may further include a first reinforcing material coupling step (S70), a second reinforcing material coupling step (S80), and a filling material filling step (S90).

First, referring to FIG. 6 , a penetrating member 10 having a cut-out hole 111 in a “卍” shape on the front and back surfaces is formed. And cut along the outer periphery of the front, left and rear surfaces except for the right side at a predetermined spaced apart position from the lower surface of the penetrating member 10 to the upper side. The fold line 12 is formed without cutting the right side. The penetrating member 10 is divided into a penetrating body 11 and a penetrating excess 13 based on the fold line 12 (S10).

The penetrating surplus 13 is folded based on the fold line 12 . The right side of the through surplus part 13 comes into contact with the right side of the through body 11 . The binding means 14 passes through the penetrating body 11 and the penetrating surplus part 13 that are in contact with each other and binds (S20).

The insertion member 20 in which the fitting hole 211 is formed is formed along the outer periphery. And the front side, the back side, and the right side are cut along the outer periphery except for the left side at a predetermined spaced apart position from the lower surface of the insertion member 20 upward. A fold line 22 is formed on the left side without cutting the left side. The insertion member 20 is divided into the insertion body 21 and the insertion surplus 23 based on the fold line 22 . And a "+"-shaped through-hole 212 is formed on the front and back surfaces of the insertion body 21 (S30).

The insertion surplus 23 is folded based on the fold line 22 . The left side of the insertion surplus part 23 comes into contact with the left side of the insertion body 21 . The binding means 24 penetrates through the insertion body 21 and the insertion surplus 23 in contact with each other (S40).

Referring to FIG. 7 , in a state in which the insertion member 20 is formed at a right angle to the penetrating member 10 , the incisions 111a are spread out to be perpendicular to the outer circumference of the insertion body 21 . The incision hole 111 is opened on the front and back surfaces of the through body 11 by spreading the incision piece 111a. Then, the insertion body 21 is inserted into the incision hole 111 . At this time, the insertion body 21 penetrates the through body 11 and forms a right angle with the through body 11 (S50). The through hole 212 is located at the center in the longitudinal direction of the through body 11 .

Referring to FIG. 8 , in a state in which the insertion body 21 is coupled to the through body 11 , the cut-out piece 111a spread out is inserted into the fitting hole 211 . As the cut piece 111a is inserted into the fitting hole 211, the insertion body 21 and the through body 11 are maintained coupled to each other without using a coupling means (S60).

Referring further to FIG. 9 , when the block unit assembly 1 in which the penetrating member 10 and the insertion member 20 are coupled to each other is formed, the block unit assemblies 1 are coupled to each other and stacked. And with further reference to FIG. 10 , the column unit assembly 2 is formed by assembling the block unit assemblies 1 .

Referring further to FIG. 11 , the masonry assembly 100 may be formed by combining the column unit assemblies 2 with each other. Then, the first reinforcing member 30a is inserted into the penetrating member 10 and both ends are fixed from the outside of the penetrating member 10 (S70). The first reinforcing material 30a passes through the through hole 212 . In addition, the second reinforcing material 30b is inserted into the insertion member 20 and both ends are fixed from the outside of the insertion member 20 (S80).

On the other hand, in the masonry assembly 100, the lower portion of the penetrating member 10n located at the bottom and the insertion member 20n located at one side is not cut. That is, only the cut-out hole 111 is formed in the penetrating member 10n, and the fitting hole 211 and the through-hole 212 are formed in the insertion member 20n. However, a hole through which the first reinforcing material 30a and the second reinforcing material 30b pass is formed, and a stopper for fixing the first reinforcing material 30a and the second reinforcing material 30b is coupled. In addition, the stopper is coupled to the injection hole of the penetrating member 10, which is located at the top and exposed, and the injection hole of the insertion member 20 located on the other side.

And the inside of the masonry assembly 100 can be reinforced by filling the inside of the penetrating member 10 and the inserting member 20 coupled to each other with a filling material (S90).

As shown in FIG. 12 , the masonry assembly 100 may be used as a structure having various forms and various uses, such as building exterior walls, interior walls, landscaping facilities, furniture, wall greening structures, flowerpots, greenhouses, and the like.

And as shown in FIGS. 13 and 14 , the plurality of masonry assemblies 100a and 100b may be fitted with each other to form a double structure. The adjacent masonry assemblies 100a and 100b are coupled to each other, but the penetrating body 11 of the penetrating member 10 of the first masonry assembly 100a faces upward and the penetrating member 10 of the second masonry assembly 100b. of the through body 11 is directed downward to face each other. At this time, the insertion surplus parts 23 of the insertion member 20 are alternately positioned with each other. The first masonry assembly 100a and the second masonry assembly 100b may be coupled to each other using the insertion surplus 23 to form a wall having a double structure.

According to the present invention, two plastic bottles are processed, one of which is separated from the top of the plastic bottle with a bottle neck in the upper direction, by cutting the opposite surface of the surface of the PET bottle in a “卍” shape to form a penetrating member 10 and a fitting hole 211. ) to form the inserted member 20 is formed.

The penetrating member 10 and the insertion member 20 are cut off the surface at a position spaced apart from the bottom to the top, folded 180 degrees outward, punched two holes in the two surfaces in contact with each other, and tied with a binding means. The surpluses (penetrating surpluses and insertion surpluses) fixed by folding out like this are inserted into the empty space of the wall to be hidden or hidden when several masonry assemblies are assembled to form a wall and then the wall and the wall are combined. It can be used for multiple purposes, such as being used as a flowerpot for greening.

The interior of the masonry assembly has a structure that can be filled with filling materials such as various plastic waste, sand, soil, fly ash or sawdust.

Accordingly, the masonry assembly of the present invention can reduce environmental pollution by recycling the plastic bottle discarded after being used for the primary purpose as a container for water or beverage, thereby reducing waste by recycling it without wasting resources. In addition, since several assemblies can be easily interconnected in the vertical direction and the left and right directions, high workability can be provided. By interconnecting masonry assemblies with specific lengths and widths through this connection method, PET bottles are used as a means of assembling structures having various shapes and uses, such as building exterior walls, interior walls, landscaping facilities, furniture, wall greening structures, flowerpots, greenhouses, etc. It can be used for secondary purposes.

In addition, since no bonding means such as mortar or adhesive is used for the masonry assembly, disassembly and assembly are easy. In particular, there is an advantage in that it is possible to assemble a stronger and more functional structure by filling the inside of the masonry assembly from recycled PET bottles with soil, sand, sawdust, mortar, fly ash, and the like.

In addition, according to the characteristics of the material filled in the inside of the masonry assembly recycled plastic bottles can be equipped with functions such as heat preservation, heat insulation, heat storage, sound absorption.

Although preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention as defined in the following claims are also provided. is within the scope of the

1: Block unit assembly 2: Column unit assembly
100: masonry assembly 10: penetrating member
11: through body 111: cutting hole
111a: incision 12: fold line
13: penetration redundancy 13L: separation distance
14, 24: binding means 10T: penetrating member thickness
20: insertion member 21: insertion body
211: fitting hole 211a: first row fitting hole
211b: second row fitting hole 212: through hole
22: fold line 23: insertion surplus
23L: Distance 20C: Center in the longitudinal direction of the insertion member
211L: fitting groove separation distance 30a: first reinforcing material
30b: second reinforcing material 40: filling member

Claims (11)

A penetrating member that is partially incised and has a plurality of incisions having a plurality of incisions formed on one surface and the other surface, respectively, and can be continuously connected along the longitudinal direction; and
An insertion member that penetrates through the penetrating member through the cutting hole and forms a right angle with the through member, a plurality of fitting holes into which the incision is inserted, and can be continuously connected along the longitudinal direction
A masonry assembly using a plastic bottle comprising a. In claim 1,
The penetrating member is
a through body in which the cut-out hole is formed;
A penetrating surplus part connected to the through body by a fold line and folded based on the fold line so that the outer periphery is in contact with the through body;
Binding means for maintaining the folded state of the penetrating excess by combining the penetrating excess and the penetrating body
includes,
In order to form the fold line at a predetermined position spaced apart from the lower surface of the penetrating member upward, it is cut along the outer periphery except for at least a portion, and is divided into the penetrating body and the penetrating excess based on the fold line, The lower end of the penetrating body is open by folding of the penetrating surplus
Masonry assembly using plastic bottles. In claim 1,
The cut-out hole is a masonry assembly using a plastic bottle formed by cutting the penetrating member in a "卍" shape. In claim 1,
The insert member is
The insertion body in which the fitting hole is formed,
An insertion surplus part connected to the insert body by a fold line and folded based on the fold line so that the outer periphery is in contact with the insert body, and
Binding means for maintaining the folded state of the insertion redundant part by combining the insertion part and the insertion body
includes,
In order to form the fold line at a predetermined position spaced apart from the lower surface of the insert member upward, it is cut along the outer periphery except for at least a portion, and is divided into the insert body and the insertion surplus based on the fold line, The lower end of the insertion body is open by folding of the insertion surplus
Masonry assembly using plastic bottles. In claim 1,
A plurality of fitting holes are formed at intervals along a circumferential direction around the outer circumference of the inserting member, and the fitting holes are formed in a first row and a second row along the longitudinal direction of the inserting member, and the fitting holes in the first row and the fitting holes of the second row are alternately positioned, and the portion between the first row and the second row is positioned inside the penetrating member
Masonry assembly using plastic bottles. In claim 5,
A masonry assembly using a plastic bottle in which a through hole connecting the inside of the penetrating member and the inside of the inserting member is formed in a portion between the first row and the second row on one surface and the other surface of the insert member. In claim 6,
a first reinforcing material inserted into one end of the penetrating member and exposed to the other end of the penetrating member through the through hole; and
A second reinforcing member penetrating the inside of the insertion member
further comprising
Masonry assembly using plastic bottles. In claim 1,
A masonry assembly using a plastic bottle further comprising a filling material positioned inside the penetrating member and the inserting member. Forming a penetrating member having a fold line by cutting one side and the other side of the upper end of the PET bottle in a “卍” shape, respectively, to form an incision hole having an incision, and cutting the outer periphery of the lower end while leaving a portion;
Folding the penetrating surplus of the penetrating member based on the fold line and combining it with the penetrating body by a binding means;
Forming a fitting hole by cutting at intervals along the outer periphery of the upper end of the PET bottle, and cutting the outer periphery of the lower end, leaving a portion to form an insert having a fold line;
Folding the insertion surplus of the insertion member based on the folding line and combining the insertion body with the folding binding means;
passing the insertion body through the through-hole through the incision hole; and
Inserting the cut piece into the inside of the insertion member through the fitting hole
A method for manufacturing a masonry assembly using a PET bottle comprising In claim 9,
In the step of forming the insert member, a through hole is formed by cutting the upper end of the PET bottle,
inserting a first reinforcing material into the inside of the penetrating member; and
inserting a second reinforcing material into the insertion member
further comprising
A method for manufacturing a masonry assembly using a PET bottle. In claim 10,
The method for manufacturing a masonry assembly using a PET bottle further comprising the step of injecting a filling material into the penetrating member and the inserting member.

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