KR102398676B1 - 3d structure and manufacturing method thereof - Google Patents

Abstract

The present invention relates to a three-dimensional structure and a method for manufacturing the same, and more particularly, a method for manufacturing a three-dimensional structure by combining a multilayer composite including a fiber-reinforced polymer phase and a metal sheet with a hybrid material, and structural integrity (structural integrity) integrity) and to a three-dimensional structure with high strength and durability.
A three-dimensional structure manufacturing method according to an embodiment of the present invention, a multi-layer forming step of thermocompression bonding a fiber reinforced polymer phase and a metallic sheet to form a multi-layer; An opening processing step of processing at least one or a plurality of openings in the multi-layer; and a bonding step of manufacturing a three-dimensional structure by combining the multi-layer having the opening and the hybrid material, wherein the bonding step includes pressing the hybrid material and the multi-layer using a press device to reinforce the fiber A polymer phase forms at least one reinforcing structure coupled to the opening and/or to the hybrid material.

Description

Three-dimensional structure and its manufacturing method {3D STRUCTURE AND MANUFACTURING METHOD THEREOF}

The present invention relates to a three-dimensional structure and a method for manufacturing the same, and more particularly, to a method for manufacturing a three-dimensional structure by combining a multilayer composite including a fiber-reinforced polymer phase and a metal sheet with a hybrid material, and structural integrity (structural integrity) integrity) and to a three-dimensional structure with high strength and durability.

The use of molded products using synthetic resins is being made widely in various industrial fields. Synthetic resin molded products used in automobiles, electronics, precision machine parts, etc. require weight reduction and improvement in physical properties, so research and development for reinforcing fibers to satisfy these requirements is also continuously continuing. For example, CFRP (Carbon Fiber Reinforced Plastics) composite material, which has recently been spotlighted as a lightweight material, is an example.

Regarding press molding using various reinforcing fibers, the molding process using prepreg (Preimpregnated Materials), which is an intermediate material in the form of a sheet in which the reinforcing fibers are pre-impregnated with a thermosetting or thermoplastic resin, is an autoclave molding, It is divided into various methods such as vacuum bag forming, sheet rolling forming, and press forming, but manual work still occupies a considerable part.

In particular, body parts such as vehicle inner doors not only have various surface structures (straight/curved, bent, opening, hole, protruding structure, attachment, etc.), but also have various structures accommodated (inserted) inside the body part. Because there is, there is a problem in that in order to apply a separate material such as reinforcing fiber after forming the steel panel separately as in the prior art, several work processes must be performed depending on the surface structure or structure. Bonding composites to metal has so far largely relied on fasteners, which require drilling holes to damage the load-bearing fibers. Although bonding using an adhesive has been used, it is difficult to combine a plurality of materials in this way, and the adhesive has a problem in that it adds material and weight.

In addition, there is a problem in that an expensive laser pretreating metal is required for the surface structure of the metal panel for bonding the reinforcing fiber intermediate material.

Therefore, the bidirectionality of continuous fiber-reinforced composite materials that provide excellent physical properties to complex 3D shapes overcome difficult designs, and have excellent high-speed molding, light weight and improved physical properties, while having automated dimensional stability, various surfaces There is a need for research and development of new materials that can reduce the manufacturing process of molded parts having a structure, thereby reducing cost and improving yield.

Korean Patent Registration No. 10-0581123B1 (Registered on May 10, 2006) Japanese Patent No. 4825348B2 (Registered on September 16, 2011)

The present invention has been devised in view of the above technical needs, and the problem to be solved by the present invention is to combine a multi-layer material and a hybrid material that can simplify the molding process while having light weight and improved physical properties to achieve structural integrity ( A method for manufacturing a three-dimensional structure having structural integrity and high strength and durability, and a three-dimensional structure manufactured by the method are provided.

In addition, the present invention can achieve the perfect full 3D formability of composite materials and isotropic 3D composite materials, and provides parts, surface structures, etc. with unique performance integration of composites and metals and design functions suitable for unique materials. Provided are a method capable of manufacturing a three-dimensional structure capable of achieving high perfection in the formation of various design structures including the single forming process, and a three-dimensional structure manufactured thereby.

In addition, the present invention provides a method for manufacturing a three-dimensional structure capable of using an existing high-speed metal and polymer manufacturing infrastructure such as a compression press or an injection molding machine as it is, and a three-dimensional structure manufactured by the method.

A three-dimensional structure manufacturing method according to an embodiment of the present invention, a multi-layer forming step of thermocompression bonding a fiber reinforced polymer phase and a metallic sheet to form a multi-layer; An opening processing step of processing at least one or a plurality of openings in the multi-layer; and a bonding step of manufacturing a three-dimensional structure by combining the multi-layer having the opening and the hybrid material, wherein the bonding step includes pressing the hybrid material and the multi-layer using a press device to reinforce the fiber A polymer phase forms at least one reinforcing structure coupled to the opening and/or to the hybrid material.

A three-dimensional structure manufacturing method according to another embodiment of the present invention, processing at least one or a plurality of openings (opening) in a metal sheet (metallic sheet), opening processing step; A fiber reinforced polymer phase (fiber reinforced polymer phase) and thermocompression bonding the metal sheet to form a multi-layer, a multi-layer forming step; Including; a bonding step of manufacturing a three-dimensional structure by combining the multi-layer having the opening and the hybrid material, wherein the bonding step presses the hybrid material and the multi-layer using a press device to form the fiber-reinforced polymer A phase forms at least one reinforcing structure coupled to the opening and/or to the hybrid material.

Here, after placing a mold on the opening formed in the multi-layer, the multi-layer and the mold are pressed using the press device, so that the fiber-reinforced polymer phase is formed in the opening and the empty space formed in the mold By flowing to the first reinforcement structure may be formed.

Here, a second reinforcing structure in which the fiber-reinforced polymer phase surrounds the hybrid material and a third reinforcing structure in which the fiber-reinforced polymer phase surrounds the edge of the metal sheet may be formed using the press device.

Here, the fiber-reinforced polymer phase is a discontinuous fiber, and may include a fiber composite material of a strand or platelet type having a random arrangement.

Here, the multi-layer in the multi-layer forming step may be formed by locally melting the contact interface between the fiber-reinforced polymer phase and the metal sheet, and then cutting it into a sheet form.

Here, the multi-layer in the multi-layer forming step further comprises an isotruss layer or foam layer, and the multi-layer forming step is thermocompression bonding the fiber-reinforced polymer phase, the isotruss layer or foam layer, and the metal sheet. to form the multi-layer.

Here, the opening may include at least one of a hole, a slit, and a slot.

Here, the hybrid material, the hybrid material, tow (or pre-impregnated preform prepreg (prepreg)), functionalized three-dimensional tow (functional 3D tow), M- tow (M-Tow = braided with glass) , natural, carbon fiber tow), a 3D isotruss structure, a metal composite 3D isotruss, and a UD tape composite may be used.

Here, the metal composite three-dimensional iso-truss structure may be a structure in which the three-dimensional iso-truss structure and a metal are combined.

Here, the metal composite three-dimensional iso-truss structure may be a structure in which the three-dimensional iso-truss structure, the metal, and the tow are combined.

Here, the tape composite may be one in which a plurality of tapes having directionality are stacked in a plurality of directions.

A three-dimensional structure according to an embodiment of the present invention includes a hybrid material; a metal sheet having at least one or multiple openings; and a fiber-reinforced polymer phase including a first reinforcing structure protruding outward through the opening of the metal sheet.

Here, the fiber-reinforced polymer phase may further include a second reinforcing structure surrounding the hybrid material.

Here, the fiber-reinforced polymer phase may further include a third reinforcing structure surrounding the edge of the metal sheet.

Here, the opening may include at least one of a hole, a slit, and a slot.

Here, the hybrid material is, tow (or pre-impregnated preform, prepreg), functionalized three-dimensional tow (functional 3D tow), M- tow (M-Tow fiber braided tow), three-dimensional iso It may be any one of a truss (3D Isotruss) structure, a metal composite 3D Isotruss, and a UD tape composite.

Here, the metal composite three-dimensional iso-truss structure may be a structure in which the three-dimensional iso-truss structure and a metal are combined.

Here, the metal composite three-dimensional iso-truss structure may be a structure in which the three-dimensional iso-truss structure, the metal, and the tow are combined.

Here, the tape composite, a plurality of tapes having one direction may be laminated in multiple directions (tailored blanks, laminate).

Here, it may further include an isotruss layer or a foam layer disposed between the metal sheet and the fiber-reinforced polymer phase.

According to the three-dimensional structure and its manufacturing method according to an embodiment of the present invention, there is an advantage in that it is possible to obtain a three-dimensional structure having structural integrity and high strength and durability.

In addition, it is possible to form a multi-layer without a separate adhesive, and by flowing the fiber-reinforced polymer phase of the multi-layer to bond to the opening formed in the multi-layer, there is also an advantage that can improve the bonding strength of the multi-layer.

In addition, there is an advantage that a three-dimensional structure of a specific shape can be manufactured by at least two press operations.

1 is a flowchart of a method for manufacturing a three-dimensional structure according to an embodiment of the present invention.
2A to 2B are diagrams for explaining the multi-layer forming step 110 shown in FIG. 1 .
3 is a view for explaining a fiber composite (fiber composite) constituting the fiber-reinforced polymer phase of the multi-layer material according to the present invention.
4 (a) to (b) are views showing other examples of the multi-layer shown in FIG.
FIG. 5 is a view for explaining the opening forming step 130 shown in FIG. 1 .
6 to 7 are views for explaining the step 150 of combining the multi-layer and hybrid material shown in FIG. 1 .
8 is a flowchart of a method for manufacturing a three-dimensional structure according to another embodiment of the present invention.
9A to 9B are views for explaining the opening processing step 210 and the multi-layer forming step 230 shown in FIG. 8 .
FIG. 10 is a diagram showing several examples of an M-Tow (fiber braided tow) as a hybrid material 400, 400'.
FIG. 11 is a diagram illustrating an example of a three-dimensional isotruss structure usable as the hybrid materials 400 and 400' shown in FIG. 7 .
12 is a description of manufacturing a three-dimensional structure of a specific shape by combining the three-dimensional iso-truss structure 400 '' and the multi-layer 115 using the three-dimensional structure manufacturing method according to the embodiment of the present invention. It is a drawing for
FIG. 13 is a diagram showing an example of a metal composite three-dimensional isotruss structure usable as the hybrid materials 400 and 400' shown in FIG. 7 .
FIG. 14 is a diagram showing an example of another metal composite 3D isotruss composite usable as the hybrid materials 400 and 400' shown in FIG. 7 .
FIG. 15 is a diagram showing an example of another UD tape composite 400'''' usable as the hybrid material 400, 400' shown in FIG. 7 .
16 is a cross-sectional view of a battery pack that may be manufactured by a method for manufacturing a 3D structure according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] Reference is made to the accompanying drawings, which show by way of illustration specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein may be embodied in other embodiments without departing from the spirit and scope of the invention with respect to one embodiment. In addition, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the detailed description set forth below is not intended to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all scope equivalents as those claimed. Like reference numerals in the drawings refer to the same or similar functions throughout the various aspects.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a flowchart of a method for manufacturing a three-dimensional structure according to an embodiment of the present invention.

Referring to FIG. 1 , the three-dimensional structure manufacturing method according to an embodiment of the present invention may include a multi-layer forming step 110 , an opening processing step 130 , and a multi-layer and hybrid material combining step 150 . there is.

In the multi-layer forming step 110, a multi-layer is formed by thermocompression bonding a fiber reinforced polymer phase and a metallic sheet. Thermocompression bonding may be performed using a hot press apparatus. When the multi-layer is formed by thermocompression bonding, manufacturing is simple, fast, and inexpensive compared to conventionally attaching fibers to a metal sheet in the form of a fabric or a laminate.

2A to 2B are diagrams for explaining the multi-layer forming step 110 shown in FIG. 1 .

Referring to Figure 2 (a), by thermocompression bonding the fiber-reinforced polymer phase 112 and the metal sheet 111, it is possible to form a multi-layer 115 as shown in Figure 2 (b).

The multi-layer 115 may be formed by locally melting the contact interface between the fiber-reinforced polymer phase 112 and the metal sheet 111 by heat, and then cutting it into a sheet shape.

Here, although it is shown that the fiber-reinforced polymer phase 112 is positioned on the metal sheet 111 , it is not limited thereto, and the position may be reversed. The bonding of the fiber-reinforced polymer phase 112 and the metal sheet 111 may be performed in various ways, such as induction/infrared heating, adhesive/scratched metal joining/coating, etc. .

The metal sheet 111 may be, for example, aluminum, but is not limited thereto, and may be a sheet formed of various metal materials. In particular, it may be made of a press-formable metal material.

The metal sheet 111 may be coated with paint.

It is not necessary to perform a surface protection, adhesive for surface, or adhesive pretreatment process on the metal sheet 111 . In the 3D structure manufacturing method according to the embodiment of the present invention, since the fiber-reinforced polymer phase 112 is formed to flow and fills the opening (hole), the fiber-reinforced polymer phase 112 and the metal sheet 111 without a separate pretreatment Adhesion may be enhanced. Therefore, even if there is corrosion (corrosion) in the metal sheet 111, there is an effect that can be bonded by directly depositing the fiber-reinforced polymer phase 112 on the metal sheet 111 without a separate pretreatment.

The fiber reinforced polymer phase 112 may be made from a mixture of fibers and polymer phases.

The polymer phase and fiber are processed and formed into a mixed material. The polymer phase is made of various resin materials such as thermoplastic resin and thermosetting resin, specifically, polypropylene (PP), polyethylene (PE), polyamide (PA), polyolefin elastomer (TPE), etc. A resin material may be used, and as the fiber, various fiber materials used as reinforcing materials such as carbon fiber, glass fiber, aramid fiber, etc. may be used alone or in combination.

Thereafter, an appropriate process may be added according to the final processing form of the polymer phase and the resin mixed material, and there may be differences in the process depending on the final processing form. Specifically, a UD tape (unidirectional tape), a strand, and a platelet through a cooling process, a pulling process, a winding process/cutting process, etc. A fiber-reinforced polymer phase 112 in the form of can be manufactured. In addition, a surface activation process for performing chemical treatment on the material that has undergone the treatment process may be further included.

Finally, the UD tape (unidirectional tape), strand (strand), platelet (platelet) type of material through a hot press process (hot press process) may be manufactured into the fiber-reinforced polymer phase 112 in a flat plate shape.

Here, when the fiber-reinforced polymer phase 112 includes carbon fibers, it is possible to improve the cooling efficiency of the manufactured 3D structure. In particular, when the 3D structure to be manufactured is a battery pack, if the fiber-reinforced polymer phase 112 is carbon fiber, heat transfer efficiency generated in the battery cell is improved, so before cooling the battery pack or warming up/preheating the battery in cold weather Efficiency can be improved and the use of other energy to raise and lower the temperature within the battery pack can be reduced.

The fiber reinforced polymer phase 112 may be a fiber reinforced polymer phase of a strand or platelet type having a random arrangement as a discontinuous fiber reinforced polymer phase (COMPOSITES). It will be described in detail with reference to FIG. 3 .

3 is a view for explaining a fiber composite (fiber composite) constituting the fiber-reinforced polymer phase of the multi-layer material according to the present invention.

The fibers constituting the fiber-reinforced polymer phase 112 preferably have a discontinuous arrangement of a platelet or strand structure, and platelets or strands are randomly arranged in a stacked form. more preferably.

Fiber composites are divided into continuous fibers (long fibers, continuous) and discontinuous fibers (short fibers, discontinuous). However, the fiber composite material, which is the material of the fiber-reinforced polymer phase 112 according to the present invention, employs discontinuous fibers (short fibers, Discontinuous) in FIG. 3 .

In this case, the fiber composite material may employ a material made of aligned and random arrangement, but it is more preferable to employ a fiber composite material having a random arrangement structure.

The structure of the fiber can be divided into bidirectional (BD, Bidirectional), unidirectional (UD, Unidirectional), aligned, random arrangement, etc., Fabric, UD tape, Tow Prepreg, M-tow fiber braided can be implemented as a platelet, a strand, etc., and is braided with glass fiber, natural fiber, carbon fiber, etc. prepreg) can also be implemented.

The fiber composite material used for the fiber-reinforced polymer phase 112 according to the present invention is a discontinuous fiber and a platelet or strand having a random arrangement structure is selected as a laminate, and the fiber composite material of the corresponding specification and metal (especially aluminum) are combined By doing so, it is possible to enhance the technical effects of the present invention.

Referring to FIG. 3 , the stiffness, strength, or resistance to creep/stress relax of the fiber composite material exhibits superior properties from left to right.

In addition, looking at the forming flow characteristics of the fiber composite material according to a predetermined pressure and heating when bonding the fiber composite material and metal, the laminated structure of a platelet or strand-type fiber and metal in a random arrangement is isotropic ( isotropic) properties. That is, by adopting a platelet or strand-type fiber in a random arrangement, it becomes possible to secure direction control and molding uniformity during forming.

On the other hand, since continuous fibers of fabric and unidirectional tape have anisotropic properties, it is difficult to control the flow of the polymer phase to a location to be designed. In particular, in the case of Tow (or Prepreg), since it has a predetermined specific direction (Tailored), it has a difficulty in producing various types of products through control of the forming flow as well.

In addition, when using a randomly arranged platelet/strand type fiber composite material compared to a regular arrangement platelet/strand type fiber composite, the above advantages are obtained. be able to Therefore, the multi-layer 110 material according to the present invention has various detailed structures, which, briefly mentioned herein, determine at least one of the flow rate and flow direction of the fiber-reinforced polymer phase melted by at least one of heating and pressurization. It exists in a processed state, whereby the efficiency of press molding can be improved, and the perfection of the final molded product can be improved.

In summary, when a platelet having a random arrangement structure is used in the manufacturing method according to the present invention, the degree of freedom of the forming flow during stamping is improved due to isotropic properties, as well as dimensional stability It also exhibits superior performance in terms of dimensional stability.

On the other hand, the conventional fabric (fabric) has the following disadvantages compared to using a strand or platelet of a random arrangement structure.

① When using fabric for design of complex three-dimensional shapes, depending on the shape of the fabric, automobile parts such as double curvature, triple curvature, or low curvature corners, or complex tetrahedral shapes, metal sheets with complex 3D shapes Problems such as intra-ply yarn sliding in the fabric laminated on top

② When fabrics are laminated on metal sheets for complex 3D designs, defects that may occur during the design stage can lower the expected mechanical performance of the final part. Sliding in fabric is a frequently observed defect, so its mechanism may not be fully understood during preforming.

③ Since the fabric for 3D shape design has a directionality, it is difficult to control the forming flow. Acts as a cause of deterioration of rigidity or surface uniformity

④ The fabric has an anisotropic structure, and in order to implement it as an isotropic structure, it can be laminated to have a predetermined angle (eg 90 degrees), but the raw material itself is expensive, so the fabric is not economical

⑤ When two or more layers of fabric are laminated on a metal sheet, it is difficult to make a 3D shape through the stamping process because heating is not performed properly.

⑥ Fabric cutting is required when supplying molding equipment, so the scrap rate is inevitably high, which leads to an increase in manufacturing cost.

⑦ Once the fabric is laminated over the metal sheet, a second injection molding or stamp molding manufacturing operation is required for 3D reinforcement and/or reinforcement design, which may not be possible for all part geometries.

⑧ It is difficult to expect dimensional stability in automated molding manufacturing.

After all, by adopting a random arrangement of platelets or strands instead of the conventional fabric, the above-mentioned disadvantages are solved and the quality of the molded product is improved.

Conventional ATL (Automated Tape Laying), AFP (Automated Fiber Placement) formed laminate or blank has a very high scrap rate compared to using a platelet having a random arrangement structure. When a laminate or blank is laminated on a metal sheet for complex 3D design, the manufacturing cost may increase, and many factors such as high cycle time, high molding cost, and difficulty in complex 3D design Disadvantages exist.

In addition, in order to bond the laminate/fabric composite to the metal, an adhesive is essential, which has problems in cost increase and weight increase due to material supply. In addition, there is a problem in that expensive pretreating (laser pretreating) is required on the surface of the metal sheet or metal panel for bonding the reinforcing fiber intermediate material.

Meanwhile, the fiber-reinforced polymer phase 112 may be composed of regenerated fibers and a polymer phase.

The multi-layer 115 has a variety of detailed structures, briefly referred to herein, in a processed state, wherein the detailed structures that determine at least one of a flow rate and a flow direction of the fiber-reinforced polymer phase melted by at least one of heating and pressurization are processed. , thereby increasing the efficiency of the press molding, it is possible to increase the degree of perfection of the final molding.

Meanwhile, FIGS. 4A to 4B are views showing other examples of the multi-layer shown in FIG. 1 .

Referring to Figure 4 (a), the multi-layer 115 ' according to another example may further include an isotruss layer (isotruss layer, 113) as compared to the multi-layer 115 shown in FIG. can The iso-truss layer may include a three-dimensional iso-truss structure as a metal material. Here, the isotruss may mean a polygonal open pyramid shape. This iso-truss layer has the advantage of improving the structural stability and strength of the multi-layer 115 ′, compared to the multi-layer 115 shown in FIG. 2 .

Referring to (b) of Figure 4, the multi-layer 115 '' according to another example may further include a foam layer (113') in addition to that of the multi-layer 115 shown in FIG. can The foam layer 113 ′ may also be referred to as a cushion layer. The foam layer 113 ′ may be made of a material such as polyurethane. The foam layer 113 ′ may have a thickness greater than that of the metal sheet 111 and/or the fiber reinforced polymer phase 112 . Since the multi-layer 115'' includes the foam layer 113', there is an advantage that noise control of the three-dimensional structure is possible when the three-dimensional structure is manufactured by multi-ching 115''. In particular, when the three-dimensional structure is a part of a product used for a power train battery pack of an airplane, automobile, or electric vehicle, noise from the outside can be removed by the foam layer 113'. There are advantages that can be

Referring back to FIG. 1 , in the opening forming step 130 , at least one or a plurality of openings are processed in the multi-layer 115 formed in step 110 . Here, the multi-layer 115 may be the multi-layers 115 ′ and 115 ″ of FIGS. 4A to 4B .

FIG. 5 is a view for explaining the opening forming step 130 shown in FIG. 1 . Here, FIG. 5 shows that an opening is formed in the multi-layer 115 shown in FIG. 2, but an opening in the multi-layer 115' and 115'' shown in FIGS. 4A to 4B. It should be understood that the formation of the is also included in the present invention.

Referring to FIG. 5 , at least one or more openings 115o are machined in the multi-layer 115 formed in step 110 .

The opening 115o may be formed to pass through the metal sheet 111 of the multi-layer 115 and a portion of the fiber-reinforced polymer phase 112 together.

The position at which the opening 115o is processed may vary depending on the 3D structure to be manufactured. The openings 115o may correspond to positions of one or more reinforcing structures, which will be described later.

The opening 115o may be processed using a laser, or the opening 115o may be processed by other methods.

The opening 115o may be defined as including at least one of a hole, a slit, and a slot.

The shape of the reinforcement structure to be described later may vary depending on the size or shape of the opening 115o.

In the step 150 of combining the multi-layer and hybrid material, the multi-layer 115 having the opening 115o and the hybrid material are combined to manufacture a three-dimensional structure.

The multi-layer 115 is inserted into a molding device or a press device, and pressure is applied from the top and/or bottom. At this time, high-temperature heat may be applied to the multi-layer material 115 together. That is, at least one of heat and pressure is applied to the multi-layer material 115 to melt the fiber-reinforced polymer phase 112 included in the multi-layer material 115 . At this time, if the lower mold of the molding apparatus is manufactured in a predetermined shape, the molten fiber-reinforced polymer phase 112 flows into the predetermined shape of the lower mold to form the structure of the predetermined shape in the 3D structure. A 3D structure with improved strength and durability can be formed by mixing a hybrid material here.

6 to 7 are views for explaining the step 150 of combining the multi-layer and hybrid material shown in FIG. 1 . Specifically, FIG. 6 is an example showing a state before the bonding of the hybrid materials 400 and 400' and the multi-layer 115, and FIG. 7 is the hybrid material 400, 400' and the multi-layer 115 are combined. This is an example of the completed 3D structure 500 .

For example, referring to FIG. 6 , the multi-layer 115 having the opening 115o and the hybrid materials 400 and 400' are positioned to face each other, and then a press apparatus (eg, a hot press apparatus) is formed. By using the pressing so that the multi-layer 115 and the hybrid materials 400 and 400 ′ are bonded to each other, the 3D structure 500 as shown in FIG. 7 can be manufactured.

An example of a detailed method of manufacturing the first reinforcing structure 510 of the 3D structure 500 shown in FIG. 7 will be described with reference to FIG. 6A .

Referring to FIG. 6A , when pressing the multi-layer 115 and the hybrid material 400 , 400 ′ to be bonded to each other using a press, a mold prepared in advance on the opening 115o of the multi-layer 115 . (mold, M) may be disposed. When pressing is applied by the press device in the state in which the mold M is disposed in this way, the fiber-reinforced polymer phase 112 is pressed and flowed, and a portion of the fiber-reinforced polymer phase 112 is injected into the opening 115o, and further It may be injected into the empty space S previously formed in the mold M. Here, the mold M may be integrally formed as a part of the press apparatus, and various types of molds may be mounted on the press apparatus as described above.

The pre-machined openings 115o in the multilayer 110 determine the flow rate and/or flow direction of the molten fiber reinforced polymer phase 112 . In addition, since the multi-layer 110 exists in a state in which rigidity is improved and the degree of freedom is increased, it is very easy to control the flow rate and/or the flow direction. That is, the flow rate/or flow direction of the fiber-reinforced polymer phase 112 may be determined according to the diameter, shape, or surface structure of the multilayer 110 defining the opening 115o, which has been pre-machined. . The above surface structure may have various patterns such as a slit pattern, a grid pattern, and a protrusion pattern, and may have a tapered shape toward the top or bottom.

After that, when the fiber-reinforced polymer phase 112 injected into the opening 115o and the empty space S of the mold M is cured, the first reinforcement protruding outward through the opening 115o of the metal sheet 111 A structure 510 may be formed. Since the first reinforcing structure 510 thus formed is integrally formed with the fiber-reinforced polymer phase 112 , structural integrity may be added.

The second reinforcing structure 520 of the 3D structure 500 illustrated in FIG. 7 may be formed in which the fiber-reinforced polymer phase 112 illustrated in FIG. 6 surrounds the hybrid material 400 . In order for the fiber-reinforced polymer phase 112 to surround the hybrid material 400 , the shape of the portion in contact with the fiber-reinforced polymer phase 112 in the pressing device may be formed to correspond to the shape of the second reinforcing structure 520 . there is. Here, a mold corresponding to the outer shape of the second reinforcing structure 520 is disposed between the press device and the fiber-reinforced polymer phase 112 , and the fiber-reinforced polymer phase 112 flows by the mold during operation of the press device. A second reinforcing structure 520 may be formed. Since the second reinforcing structure 510 thus formed is integrally formed with the fiber-reinforced structure 112 , structural integrity may be added.

The third reinforcing structure 530 of the 3D structure 500 shown in FIG. 7 may be formed in which the fiber-reinforced polymer phase 112 shown in FIG. 6 surrounds the edge of the metal sheet 111 . In order for the fiber-reinforced polymer phase 112 to surround the edge of the metal sheet 111 , the shape of the portion in contact with the fiber-reinforced polymer phase 112 in the pressing device is formed to correspond to the shape of the third reinforcing structure 530 . can be Here, a mold corresponding to the external shape of the third reinforcing structure 530 is disposed between the pressing device and the fiber-reinforced polymer phase 112, so that the fiber-reinforced polymer phase 112 flows during the operation of the pressing device and is formed by the mold. A third reinforcing structure 530 may be formed. Since the third reinforcing structure 530 thus formed is integrally formed with the fiber-reinforced structure 112 , structural integrity may be added.

The 3D structure 500 illustrated in FIG. 7 may further include other reinforcing structures in addition to the first to third reinforcing structures 510 , 520 , and 530 described above. For example, it may further include a fourth reinforcing structure 540 surrounding the functionalized three-dimensional hybrid material 400 ′, and a fifth reinforcing structure 540 in the form of a knob for strengthening bonding force with the metal sheet 111 . A reinforcing structure 550 may be further included. In addition, a sixth reinforcing structure 560 may be further included to strengthen the bonding force with the metal sheet 111 and to couple the 3D structure 500 with another structure or assembly.

Here, the fourth reinforcing structure 540 may be manufactured in the same or similar manner as the second reinforcing structure 520 , and the fifth reinforcing structure 550 and the sixth reinforcing structure are the same as the first reinforcing structure 510 . Or it can be prepared in a similar way.

As such, in the method for manufacturing a three-dimensional structure according to an embodiment of the present invention, a multi-layer is formed by combining a fiber-reinforced polymer phase and a metal sheet without another adhesive, and an opening is processed in the formed multi-layer, and the By pressing, a user's desired 3D structure can be manufactured quickly, simply and inexpensively, and the formation of ribs, knobs, features, textures, encapsulation, and edges of the 3D structure is free. There are also advantages.

8 is a flowchart of a method for manufacturing a three-dimensional structure according to another embodiment of the present invention.

The three-dimensional structure manufacturing method according to another embodiment of the present invention shown in FIG. 8 may include an opening processing step 210 , a multi-layer forming step 230 , and a multi-layer and hybrid material bonding step 250 . .

The 3D structure 500 illustrated in FIG. 7 may be manufactured by the method for manufacturing a three-dimensional structure according to another embodiment of the present invention illustrated in FIG. 8 .

The difference is that the three-dimensional structure manufacturing method according to another embodiment of the present invention shown in FIG. 8 is different from the three-dimensional structure manufacturing method according to an embodiment of the present invention shown in FIG. 7 , the opening processing step 210 ) is performed before the multi-layer forming step 230 . This will be described in detail with reference to FIG. 9 .

9A to 9B are diagrams for explaining the opening processing step 210 and the multi-layer forming step 230 shown in FIG. 8 .

Referring to FIG. 9A , at least one or a plurality of openings 111o are machined in the metal sheet 111 ′.

The opening 111o may be formed so that a portion of the metal sheet 111' penetrates.

The position at which the opening 111o is processed may vary depending on the 3D structure to be manufactured. The opening 111o may correspond to a position of one or a plurality of reinforcing structures to be described later.

The opening 111o may be processed using a laser, or the opening 111o may be processed by other methods.

The opening 111o may be defined as including at least one of a hole, a slit, and a slot.

The shape of the reinforcement structure to be described later may vary depending on the size or shape of the opening 111o.

Referring to FIG. 9B , a multi-layer 115 ′ is formed by forming a fiber-reinforced polymer phase 112 ′ on the metal sheet 111 ′. Here, the fiber-reinforced polymer phase 112 ′ and the metal sheet 111 ′ may be thermocompression-bonded to form a multi-layer 115 ′.

The multi-layer 115 ′ may be formed by locally melting the contact interface between the fiber-reinforced polymer phase 112 ′ and the metal sheet 111 ′ by heat, and then cutting it into a sheet shape.

On the other hand, since the multi-layer and hybrid material combining step 250 shown in Fig. 8 is the same as the multi-layer and hybrid material combining step 150 described above in Figs. .

The three-dimensional structure manufacturing method according to another embodiment of the present invention shown in FIG. 8 can also obtain the same effect as the three-dimensional structure manufacturing method according to the embodiment of the present invention shown in FIG.

Meanwhile, the hybrid materials 400 and 400' shown in FIGS. 6 to 7 will be described in detail below.

Hybrid materials 400 and 400' are, Tow, the pre-impregnated preform (the prepreg), functional 3D tow, M-Tow, fiber braided Tow, 3 It may be any one of a 3D Isotruss structure, and a metal composite 3D Isotruss structure. Hereinafter, each will be described in detail with reference to the accompanying drawings.

Tow is a hybrid material also called prepreg (　 the pre-impregnated preform), and is a material in which a polymer compound and a fiber material are mixed.

M-Tow (fiber braided tow) may be a composite material including a hybrid material strand such as tow, a fiber (carbon, glass, natural, basalt) layer, and a coating layer. Examples of the M-toe will be described with reference to FIG. 10 .

FIG. 10 is a diagram showing several examples of M-tows usable as hybrid materials 400 and 400' shown in FIG. 7 . Specifically, (a) of FIG. 10 is an example of the M-tow, and FIG. 10 (b) is another example of the M-tow.

Referring to Figure 10 (a), the M-toe 100 is a hybrid material strand 120, a fiber layer 140 surrounding the hybrid material strand 120, and a coating layer 160 surrounding the fiber layer 140. may include

Referring to FIG. 10 (b), the M-toe 300 is a hybrid material strand 320, a coating layer 360 surrounding the hybrid material strand 120, and a fiber layer 340 surrounding the coating layer 360. may include

10 (a) to (b), the hybrid material strands 120 and 320 may include at least one of a polymer compound and a fiber material. The shape of the hybrid material strands 120 and 320 may include a band shape as well as a strand shape. For example, the shape of the hybrid material strands 120 , 320 may be substantially the same as the shape of a continuous strand, yarn, tow, bundle, band, tape, or the like. The hybrid material strands 120 and 320 may be a major component that determines the mechanical performance (rigidity, durability, impact resistance, etc.) of the hybrid material 300 as the final product.

The polymer compound may include at least one of a thermoplastic resin and a thermosetting resin. For example, the high molecular compound is polylactic acid, polyethylene, polypropylene, polyamide, ABS, polymethyl methacrylate, polycarbonate, polyethylene terephthalate, polybutylene terephthalate, polyetherimide, polyphenylene sulfide, poly It may include at least one of ether ether ketone, ethylene vinyl acetate, polyurethane, epoxy, unsaturated polyester, polyimide, and phenolic.

The fiber material may include at least one of glass fiber, carbon fiber, natural fiber, aramid fiber, ceramic fiber, viscous fluid fiber, shape memory alloy fiber, optical fiber, and piezoelectric fiber. When mixed with the polymer compound, the fiber material may be a reinforcing material of the polymer compound. Some fibrous materials may be encapsulated. For example, the fibrous material may be coated in several layers. In this case, the fiber material may have a structure of a cable having a small diameter.

The fiber layers 140 and 340 may include at least one of a thermoplastic resin or a thermosetting resin. For example, the fiber layers 140 and 340 may include polylactic acid, polyethylene, polypropylene, polyamide, ABS, polymethyl methacrylate, polycarbonate, polyethylene terephthalate, polybutylene terephthalate, polyetherimide, and polyphenyl. It may include at least one of lensulfide, polyether ether ketone, ethylene vinyl acetate, polyurethane, epoxy, unsaturated polyester, polyimide, and phenolic.

Here, the fiber layers 140 and 340 may include carbon. When the fiber layers 140 and 340 include carbon, heat transfer efficiency may be improved, and rigidity may be increased. In particular, when the 3D structure to be manufactured is a battery pack, using M-tow as a hybrid material, and when the fiber layer of M-tow contains carbon, heat transfer efficiency is improved, so that the cooling efficiency of the battery pack is improved There is an advantage in that energy can be saved as the use of other energy for lowering the temperature in the battery pack can be reduced.

The fibrous layers 140 and 340 may be braided and formed on the hybrid material strands 120 and 320 . The braided fibrous layers 140 , 340 may be formed by a radially applied strain or load by the hybrid material strands 120 . It can have sufficient rigidity to withstand the load.

The coating layers 160 and 360 may be a coating polymer. The coating polymer may allow the three-dimensional object to be formed based on the M-tows 100 and 300 to have suitable bonding. In an embodiment in which the coating layer 160 is positioned on the surface of the tow 100 , a coating polymer having a high viscosity may be selected.

10 (a) to (b) according to the embodiment shown in the M-tow (100, 300) is a hybrid material strand (120, 320), the fiber layer (140, 340) and the coating layer (160, 360) between Based on the physical interaction, it can have high rigidity, durability, and impact properties.

The functionalized 3D tow is a functional modification of the above-described tow or M-tow, and may be a hybrid material 400 ′ having an empty space therein, as shown in FIG. 7 . Optical fibers, piezoelectric fibers, electric cables, etc. are arranged in the empty space inside, the empty space inside is used as an air flow path in the air conditioning system, functions as a tube through which water, cooling liquid, etc. flows, or parts such as a sensing filament or sensor There is an advantage that it can also function as a receiving space to be inserted.

FIG. 11 is a diagram showing an example of a three-dimensional isotruss structure usable as the hybrid materials 400 and 400' shown in FIG. 7 .

The three-dimensional iso-truss structure means that, as shown in FIG. 11 , a metal material has a three-dimensional iso-truss structure. Here, the isotruss may mean a polygonal open pyramid shape. Such a three-dimensional isotruss structure has advantages of structural stability and high strength.

12 is a description of manufacturing a three-dimensional structure of a specific shape by combining the three-dimensional iso-truss structure 400 '' and the multi-layer 110 using the three-dimensional structure manufacturing method according to the embodiment of the present invention. It is a drawing for

As shown in FIG. 12 , the three-dimensional iso-truss structure 400 ″ has the advantage of further improving the strength and durability of the completed three-dimensional structure.

FIG. 13 is a diagram showing an example of a metal composite three-dimensional isotruss structure usable as the hybrid materials 400 and 400' shown in FIG. 7 .

Referring to FIG. 13 , the metal composite 3D iso-truss structure 400'' may be a composite of the 3D isotruss structure 400'' and the metal M, as shown in FIG. 11 or FIG. 12 . there is. When a three-dimensional structure is manufactured using such a metal composite three-dimensional iso-truss structure 400'' as a hybrid material, the strength and durability of the manufactured three-dimensional structure can be further improved than in FIG. 11 or 12. there is.

FIG. 14 is a diagram showing an example of another metal composite 3D isotruss composite usable as the hybrid materials 400 and 400' shown in FIG. 7 .

Referring to FIG. 14 , another metal composite three-dimensional isotruss structure 400 ″″ is added to the three-dimensional isotruss structure 400 ″ and the metal M as shown in FIG. 11 or 12 . Tow, or as shown in FIG. 10 M- tow (T) may be further included in the composite. If a three-dimensional structure is manufactured using the metal composite three-dimensional isotruss structure 400''' as a hybrid material, there is an advantage that the strength and durability of the manufactured three-dimensional structure can be further improved than in FIG. 13 .

FIG. 15 is a diagram illustrating an example of another tape composite 400'''' usable as the hybrid material 400, 400' shown in FIG. 7 .

The UD tape composite 400''''' may include a plurality of UD tapes shown in FIG. 3 .

The UD tape composite 400 ″″″ shown in FIG. 15 includes a plurality of UD tapes 1500 . A plurality of UD tapes 1500 may be arranged to overlap each other in various directions. For example, as shown in FIG. 15 , a plurality of first tapes may be disposed along a first direction d1, and a plurality of second tapes may be disposed on the plurality of first tapes in a second direction d2. ), a plurality of third tapes may be disposed along a third direction d3 on the plurality of second tapes, and a plurality of fourth tapes may be disposed on the plurality of third tapes. It may be disposed along the 4 directions d4.

Here, a plurality of first tapes, a plurality of second tapes, a plurality of third tapes, and a plurality of fourth tapes are sequentially stacked from bottom to top, and then some portions of a plurality of fourth tapes disposed on top The plurality of first tapes, the plurality of second tapes, the plurality of third tapes, and the plurality of fourth tapes may be bonded to each other by applying a predetermined pressure thereto. In this case, as shown in FIG. 15 , a predetermined scratch 1550 may remain at the position where the pressure is applied.

Here, the first direction d1 and the second direction d2 may be perpendicular to each other, the third direction d3 and the fourth direction d4 may be perpendicular to each other, and the first direction d1 and the second direction d4 may be perpendicular to each other. The three directions d3 may form an acute angle, for example, at an angle of 45 degrees.

Here, FIG. 15 shows the tape composite 400''''' as an example, in which a plurality of tapes may be disposed in a fifth direction or more.

As described above, since the tape composite 400 ″″″ stacked to have various directions using a plurality of tapes 1500 having one directionality has various directions, the 3D structure shown in FIG. 1 or FIG. 8 is manufactured. When used as a hybrid material in the method, the fiber composite can flow along the various directions of the tape composite 400 ″″″. Therefore, the fiber composite can flow in several directions without being limited by the single directionality of one tape 1500, so that a user's desired 3D structure from 2D to 3D can be manufactured.

In particular, when the tape composite 400'''' shown in FIG. 15 is used as a hybrid material of the 2D to nearly 3D structure manufacturing method shown in FIG. 1 or FIG. 8, a large area or large part such as a part of an airplane There is also the advantage of being able to manufacture at one time.

16 is a cross-sectional view of a battery pack that may be manufactured by a 3D structure manufacturing method according to an embodiment of the present invention.

The battery pack illustrated in FIG. 16 may be a box for accommodating an electric battery of an electric vehicle. These battery packs are a battery module (battery module, 1610), a frame (frame, 1630), a battery module tray (battery module tray, 1650), a cooling part (cooling components, 1670) and a battery cover part (battery cover components, 1690) may include

The battery module 1610 may be a module that supplies power to the electric vehicle. A number may be disposed within the battery pack.

The frame 1630 may be for separating each of the plurality of battery modules 1610 and protecting each of the battery modules 1610 . The battery module 1610 may be disposed between two adjacent frames 1630 .

The battery module tray 1650 may be a tray on which a plurality of battery modules 1610 are mounted. A plurality of frames 1630 may be spaced apart from each other on the battery module tray 1650 .

The cooling unit 1670 may be disposed under the battery module tray 1650 , and may reduce the internal temperature of the battery pack by absorbing heat generated from the battery module 1610 .

The battery cover unit 1690 may constitute the external shape of the battery pack, and the battery module 1610 , the frame 1630 , the battery module tray 1650 , and the cooling unit 1670 are disposed within the battery cover unit 1690 . can be

The battery cover unit 1690 may include a lower plate 1691 , a side plate 1693 , and an upper plate 1695 . A cooling unit 1670 may be disposed on the lower plate 1691 , and the side plate 1693 may be coupled to an edge of the lower plate 1691 . The top plate 1695 may be disposed on the side plates 1693 to seal the battery module 1610 in the battery pack.

In the battery pack shown in Fig. 16, the battery cover unit 1690, the frame 1630 and the cooling unit 1670 are manufactured through the 3D structure manufacturing method according to the embodiment of the present invention shown in Fig. 1 or Fig. 8 above. can do. Additionally, the battery module tray 1650 may be manufactured together with the battery cover unit 1690 , the frame 1630 , and the cooling unit 1670 through the 3D structure manufacturing method according to the embodiment of the present invention.

For example, the cooling unit 1650 may be formed of the hybrid material 400' and the metal sheet 111 shown in FIGS. 6 to 7, and the lower plate 1691 and the side plate ( 1693) and at least two or more of the frame 1630 may be formed of the fiber-reinforced polymer phase 112 shown in FIGS. 6 to 7 . Furthermore, the battery module tray 1650 may also be formed from the fiber-reinforced polymer phase 112 at a time.

Here, the cooling unit 1650 may be formed of the hybrid material 400 ′ and the metal sheet 111 shown in FIGS. 6 to 7 , and in particular, the cooling water fills the internal empty space formed in the hybrid material 400 ′. It is possible to lower the temperature inside the battery pack by flowing through it, and there is an advantage in that the metal sheet 111 increases thermal conductivity to quickly spread the temperature inside the battery pack. As described above, if the 3D structure manufacturing method according to the embodiment of the present invention is used, there is an advantage that the cooling unit 1650 shown in FIG. 16 can be manufactured in one process.

Meanwhile, the upper plate 1695 of the battery cover unit 1690 may be separately manufactured and mounted on the side plate 1693 of the battery cover unit 1690 after the battery module 1610 is mounted in the battery pack.

In the above, the embodiment has been mainly described, but this is only an example and does not limit the present invention, and those of ordinary skill in the art to which the present invention pertains are not exemplified above in a range that does not depart from the essential characteristics of the present embodiment. It can be seen that various modifications and applications are possible. For example, each component specifically shown in the embodiment can be implemented by deformation|transformation. And differences related to such modifications and applications should be construed as being included in the scope of the present invention defined in the appended claims.

111: metal sheet
112: fiber reinforced polymer phase
115: multi-layer
115o: opening

Claims (21)

A multi-layer forming step of thermocompression bonding a fiber reinforced polymer phase and a metallic sheet to form a multi-layer;
An opening processing step of processing at least one or a plurality of openings in the multi-layer; and
Combining the multi-layer having the opening and the hybrid material to produce a three-dimensional structure, a bonding step; including,
wherein the bonding step presses the hybrid material and the multi-layer using a press device to form at least one reinforcing structure in which the fiber-reinforced polymer phase is bonded to the opening and/or the hybrid material. Way.
An opening processing step of processing at least one or a plurality of openings in a metallic sheet;
A fiber reinforced polymer phase (fiber reinforced polymer phase) and thermocompression bonding the metal sheet to form a multi-layer, a multi-layer forming step;
Combining the multi-layer having the opening and the hybrid material to produce a three-dimensional structure, a bonding step; including,
The bonding step includes pressing the hybrid material and the multi-layer using a press device to form at least one reinforcing structure in which the fiber-reinforced polymer phase is bonded to the opening and/or the hybrid material,
The fiber-reinforced polymer phase is a method of manufacturing a three-dimensional structure, comprising a fiber composite of a strand or platelet type having a random arrangement, wherein the fiber is discontinuous (discontinuous) fibers.
According to claim 1 or 2, wherein the combining step,
After placing a mold on the opening formed in the multi-layer, the multi-layer and the mold are pressed using the press device, so that the fiber-reinforced polymer phase flows into the opening and the empty space formed in the mold. By being, the first reinforcement structure is formed, a three-dimensional structure manufacturing method.
According to claim 1 or 2, wherein the combining step,
A method of manufacturing a three-dimensional structure, using the press device to form a second reinforcing structure in which the fiber-reinforced polymer phase surrounds the hybrid material and a third reinforcing structure in which the fiber-reinforced polymer phase surrounds an edge of the metal sheet.
The method of claim 1,
The fiber-reinforced polymer phase is a method of manufacturing a three-dimensional structure, comprising a fiber composite of a strand or platelet type having a random arrangement, wherein the fiber is discontinuous (discontinuous) fibers.
According to claim 1 or 2, wherein the multi-layer in the multi-layer forming step,
After the fiber-reinforced polymer phase and the contact interface of the metal sheet are locally melted and formed, the three-dimensional structure manufacturing method is formed by cutting into a sheet form.
3. The method of claim 1 or 2,
The multi-layer in the multi-layer forming step further comprises an isotruss layer or a foam layer,
The multi-layer forming step, the fiber-reinforced polymer phase, the isotruss layer or foam layer and thermocompression bonding the metal sheet to form the multi-layer, a three-dimensional structure manufacturing method.
3. The method of claim 1 or 2,
The opening, including at least one of a hole, a slit, and a slot, a three-dimensional structure manufacturing method.
3. The method of claim 1 or 2
The hybrid material is, tow (Tow), functionalized three-dimensional tow (functional 3D tow), M-tow (M-Tow), three-dimensional isotruss (3D Isotruss) structure, metal composite three-dimensional isotrus (metal composite 3D) Isotruss) structure and any one of the tape composite, a three-dimensional structure manufacturing method.
10. The method of claim 9,
The metal composite three-dimensional iso-truss structure is a structure in which the three-dimensional iso-truss structure and a metal are combined, a three-dimensional structure manufacturing method.
10. The method of claim 9,
The metal composite three-dimensional iso-truss structure is a structure in which any one of the three-dimensional iso-truss structure, the metal, and the tow and the M-tow is combined, a three-dimensional structure manufacturing method.
10. The method of claim 9,
The tape composite is, a three-dimensional structure manufacturing method that a plurality of tapes having one direction are stacked in a plurality of directions.
hybrid materials;
a metal sheet having at least one or multiple openings; and
A fiber-reinforced polymer phase comprising a first reinforcing structure protruding outwardly through the opening of the metal sheet;
wherein the fiber reinforced polymer phase further comprises a second reinforcing structure surrounding the hybrid material.
delete 14. The method of claim 13,
The fiber-reinforced polymer phase further comprises a third reinforcing structure surrounding an edge of the metal sheet.
14. The method of claim 13,
The opening, including at least one of a hole, a slit, and a slot, a three-dimensional structure.
14. The method of claim 13
The hybrid material is, tow (Tow), functionalized three-dimensional tow (functional 3D tow), M-tow (M-Tow), three-dimensional isotruss (3D Isotruss) structure, metal composite three-dimensional isotrus (metal composite 3D) Isotruss) structures and tape composites, which are three-dimensional structures.
18. The method of claim 17,
The metal composite three-dimensional iso-truss structure is a structure in which the three-dimensional iso-truss structure and a metal are combined, a three-dimensional structure.
18. The method of claim 17,
The metal composite three-dimensional iso-truss structure, the three-dimensional iso-truss structure, the metal, and the tow and the M-tow any one of a combined structure, a three-dimensional structure.
18. The method of claim 17,
The tape composite is, a three-dimensional structure in which a plurality of tapes having one direction are stacked in a plurality of directions.
14. The method of claim 13,
A three-dimensional structure, further comprising an isotruss layer or a foam layer disposed between the metal sheet and the fiber-reinforced polymer phase.

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