阅读说明：本技术 一种高强隔热金属点阵夹芯壳体及制备方法 (High-strength heat-insulation metal lattice sandwich shell and preparation method thereof ) 是由 刘雪峰 李昂 万祥睿 汪鑫 于 2021-09-27 设计创作，主要内容包括：本发明公开了一种高强隔热金属点阵夹芯壳体及制备方法,属于金属材料结构设计及加工技术领域。该金属点阵夹芯壳体包括：用于提高金属点阵夹芯壳体的强度和抗冲击能力,并承受大部分挤压和冲击能量的金属外壁板；由垂直于所述金属外壁板且相互并列排布的单层金属体心立方点阵单胞组成、点阵单胞杆的半径沿纵向传热方向逐渐减小且纵向等效传热系数小于等于0.1W/(m·℃)的金属点阵层；用于支撑所述金属点阵层的金属内壁板。采用金属3D打印技术对金属点阵夹芯壳体进行一体化打印成形。本发明的金属点阵夹芯壳体及制备方法具有制备工序简单、生产成本低、适用性广、隔热效果好且兼顾强度等优点。(The invention discloses a high-strength heat-insulation metal lattice sandwich shell and a preparation method thereof, belonging to the technical field of structural design and processing of metal materials. The metal lattice sandwich shell comprises: the metal outer wall plate is used for improving the strength and the impact resistance of the metal dot matrix sandwich shell and bearing most of extrusion and impact energy; the metal lattice layer consists of single-layer metal body-centered cubic lattice unit cells which are vertical to the metal outer wall plate and are mutually arranged in parallel, the radius of lattice unit cell rods is gradually reduced along the longitudinal heat transfer direction, and the longitudinal equivalent heat transfer coefficient is less than or equal to 0.1W/(m DEG C); and the metal inner wall plate is used for supporting the metal dot matrix layer. And integrally printing and forming the metal dot matrix sandwich shell by adopting a metal 3D printing technology. The metal lattice sandwich shell and the preparation method have the advantages of simple preparation process, low production cost, wide applicability, good heat insulation effect, strength and the like.)

1. A high-strength heat-insulation metal dot matrix sandwich shell is characterized by comprising:

the metal outer wall plate is used for improving the strength and the shock resistance of the high-strength heat-insulation metal dot matrix sandwich shell and bearing most of extrusion and impact energy;

the metal lattice layer is internally composed of metal body-centered cubic lattice unit cells which are perpendicular to the metal outer wall plate and are arranged in parallel, the radius of each lattice unit cell rod is gradually reduced along the longitudinal heat transfer direction, the longitudinal equivalent heat transfer coefficient of the metal lattice layer is less than or equal to 0.1W/(m.DEG C), and transverse heat dissipation is increased while the longitudinal heat transfer of the metal lattice layer is reduced, so that the metal lattice layer has light weight, high strength and energy absorption effect and excellent heat insulation performance;

and the metal inner wall plate is used for supporting the metal dot matrix layer.

2. The high-strength heat-insulation metal lattice sandwich shell as claimed in claim 1, wherein the thickness of the metal outer wall plate is 3-10 mm, the thickness of the metal lattice layer is 5-50 mm, and the radius r of the joint end of the lattice unit cell rod and the metal outer wall plate is₁0.5-2.5 mm, and the radius r of the joint end of the lattice unit cell rod and the metal inner wall plate₂0.1-0.5 mm, and the thickness of the metal inner wall plate is 0.5-1 mm.

3. The high-strength heat-insulation metal lattice sandwich shell according to claim 1, wherein the high-strength heat-insulation metal lattice sandwich shell is made of at least one of aluminum alloy, titanium alloy, high-temperature alloy or steel; the high-strength heat-insulation metal lattice sandwich shell can bear the extrusion stress of 700-2000 MPa and can bear the impact of 5000-20000 g of acceleration.

4. The high-strength heat-insulation metal lattice sandwich shell according to claim 1, wherein the lattice unit cell is provided with a node which is connected with the lattice unit cell through a reinforcing rod in a direction perpendicular to a heat transfer direction, so that the node of the lattice unit cell is prevented from being damaged due to stress concentration while the transverse heat dissipation is further increased; the lattice unit cell has at least one of a tetrahedral type, a polyhedral type, a kagome type or a diamond type.

5. The high-strength heat-insulation metal lattice sandwich shell as claimed in claim 1, wherein the radius of the lattice unit cell rod is constant along the longitudinal heat transfer direction, and the side length l of the lattice unit cell, the radius r of the lattice unit cell rod and the heat transfer coefficient k of the metal material satisfyThe lattice unit cell is in a body-centered tetragonal structure, three side lengths a, b and c of the lattice unit cell, and the radius r of a lattice unit cell rod₁And r₂And the heat transfer coefficient k of the metal material satisfies the relationship

6. A preparation method of a high-strength heat-insulation metal lattice sandwich shell is characterized in that the preparation method is used for preparing the metal lattice sandwich shell according to any one of claims 1 to 5, and the preparation method comprises the following steps:

step 1: constructing a three-dimensional model of the metal dot matrix sandwich shell;

step 2: slicing the three-dimensional model by using layered slicing software;

and step 3: dividing the three-dimensional model after slicing into a filling path and a contour by using path planning software, and respectively carrying out forming path planning processing on the filling path and the contour to obtain a filling forming path and a contour forming path;

and 4, step 4: using metal powder, metal wires or metal blocks as raw materials, and sequentially performing filling and single-layer printing and forming of the outline according to the filled forming path and the outline forming path by using a 3D printing system of metal 3D printing equipment;

and 5: and (4) repeating the step (4) until the metal dot matrix sandwich shell is obtained after forming.

7. The method for preparing a high strength heat insulating metal dot matrix sandwich shell according to claim 6, wherein the 3D printing system is at least one of a laser beam based 3D printing system, an electron beam based 3D printing system, an ion beam based 3D printing system or a liquid flow fast cooling based 3D printing system.

8. The method for preparing a high strength heat insulating metal lattice sandwich shell according to claim 6, wherein the metal outer wall plate of the high strength heat insulating metal lattice sandwich shell is subjected to strengthening heat treatment, and the metal lattice layer of the high strength heat insulating metal lattice sandwich shell is subjected to toughening treatment.

9. The utility model provides a 3D printing system of thermal-insulated metal dot matrix core shell of excelling in, its characterized in that, the system includes:

a processor and a memory for storing executable instructions;

wherein the processor is configured to execute the executable instructions to perform the method of making a high tensile insulating metal lattice sandwich shell according to any one of claims 6 to 8.

10. A computer readable storage medium, on which a computer program is stored, which, when being executed by a processor, carries out the method of manufacturing a high strength insulated metal lattice sandwich shell according to claims 6 to 8.

Technical Field

The invention belongs to the technical field of structural design and processing of metal materials, and particularly relates to a high-strength heat-insulation metal dot matrix sandwich shell and a preparation method thereof.

Technical Field

The metal lattice sandwich shell is a metal shell consisting of inner and outer metal wall plates and a middle metal lattice layer formed by periodically arranging lattice unit cells. The metal lattice sandwich shell is usually made of aluminum alloy, titanium alloy, steel and the like, has the characteristics of light weight, high specific strength, impact resistance and the like, and has wide application in cabins, protective bodies, data recorders, pressure containers, fuel tanks and the like of aerospace, transportation, engineering machinery and the like.

In order to reduce the weight of the metal lattice sandwich shell, the metal inner and outer wall plates of the existing metal lattice sandwich shell are generally thinner, so that the metal lattice layer of the existing metal lattice sandwich shell bears larger force. In order to improve the structural strength of the metal lattice layer and prevent the metal lattice layer from being damaged when being stressed, the density of the metal lattice layer is usually over 30%. This results in a metal lattice sandwich shell with a limited thermal insulation capability due to the fact that although the longitudinal heat conduction area of the metal lattice layer is smaller than that of the solid metal material, the longitudinal equivalent heat transfer coefficient is usually higher than 1W/(m.cndot.) C, and an effective method for promoting the lateral heat dissipation is lacked. In addition, with the increasingly harsh use environment of the metal lattice sandwich shell, higher requirements are put forward on the strength, the heat insulation capability and the like of the metal lattice sandwich shell. In order to meet the development requirements of the metal lattice sandwich shell, the currently adopted measures mainly include the following two measures:

(1) the lattice unit cell structure and the arrangement mode of the metal lattice layer are designed, the stress distribution of the metal lattice layer is optimized, and the specific strength of the metal lattice layer is improved. The method can improve the strength of the metal dot matrix sandwich shell to a certain extent, but cannot improve the heat insulation capability of the metal dot matrix sandwich shell.

(2) According to the characteristics of stress and heat conduction in the metal lattice layer, the metal lattice layer material is designed into a gradient transition form from high-heat-conductivity high-strength metal to low-heat-conductivity low-strength ceramic and the like. The method gives consideration to the strength and the heat insulation capability of the metal lattice sandwich shell to a certain extent, but the preparation process of the gradient material lattice layer is complex and the production cost is higher.

In addition, the existing metal lattice sandwich shell is generally formed by casting integrally, or by forming a metal inner wall plate and a metal outer wall plate by rolling and the like, then forming a metal lattice by stamping, folding or cutting and the like, and then connecting the metal inner wall plate and the metal lattice by diffusion bonding, welding, riveting or gluing. The preparation methods also have the problems of complex preparation process, high production cost, poor applicability, difficulty in meeting the use requirements of the shell and the like.

Therefore, the development and preparation process is simple, the production cost is low, the applicability is wide, the heat insulation effect is good, and the strength of the metal lattice sandwich shell and the preparation method are considered, so that the development and preparation method has very important significance.

Disclosure of Invention

Aiming at the defects of complex preparation process, high production cost, poor applicability, poor heat insulation effect, incapability of considering strength and the like of the traditional metal lattice sandwich shell, the invention aims to provide a high-strength heat insulation metal lattice sandwich shell and a preparation method thereof. The metal lattice sandwich shell adopts a single-layer lattice unit cell structure in the longitudinal heat transfer direction, and the radius of a lattice unit cell rod is gradually reduced along the longitudinal heat transfer direction, so that the longitudinal equivalent heat transfer coefficient of a metal lattice layer is reduced to be lower than 0.1W/(m.DEG C) compared with the solid structure with the same thickness, the transverse equivalent heat transfer coefficient of the larger radius side of the lattice unit cell rod is not obviously reduced, the longitudinal heat transfer of the metal lattice layer is reduced, the transverse heat dissipation is increased, and the heat insulation capability of the metal lattice sandwich shell is improved; by increasing the thickness of the metal outer wall plate, the strength and the impact resistance of the metal dot matrix sandwich shell are improved, and simultaneously, the metal dot matrix layer is protected, so that the problems that the traditional metal dot matrix sandwich shell is poor in heat insulation effect, cannot give consideration to the strength and the like are solved; the designed metal dot matrix sandwich shell is integrally formed by adopting a metal 3D printing technology, so that the problems of complex working procedures, high production cost, poor applicability, difficulty in meeting the use requirements of the shell performance and the like in the traditional preparation process of the metal dot matrix sandwich shell are solved.

According to a first aspect of the invention, a high-strength heat-insulating metal dot matrix sandwich shell is provided, which comprises a metal outer wall plate, a metal dot matrix layer and a metal inner wall plate. The thickness of the metal outer wall plate is 3-10 mm, and the metal outer wall plate is used for improving the strength and the shock resistance of the high-strength heat-insulation metal dot matrix sandwich shell and bearing most of extrusion and impact energy; the thickness of the metal lattice layer is 5-50 mm, the metal lattice layer is internally composed of metal body-centered cubic lattice unit cells which are perpendicular to the metal outer wall plate and are arranged in parallel, the side length l of each lattice unit cell is the same as the thickness of the metal lattice layer, the radius of each lattice unit cell rod is gradually reduced along the longitudinal heat transfer direction, and the radius r of the end, connected with the metal outer wall plate, of each lattice unit cell rod is₁0.5-2.5 mm, and the radius r of the joint end of the lattice unit cell rod and the metal inner wall plate₂0.1-0.5 mm, the side length l of the lattice unit cell, and the radius r of the lattice unit cell rod₁And r₂And the heat transfer coefficient k of the metal material satisfiesThereby leading the longitudinal equivalent heat transfer coefficient of the metal lattice layer to be less than or equal to 0.1W/(m DEG C), reducing the longitudinal heat transfer of the metal lattice layer and simultaneously increasing the transverse heat dissipation, and leading the metal lattice layer to have light weight, high strength and energy absorption effect and simultaneously have excellent heat insulation performance(ii) a The thickness of the metal inner wall plate is 0.5-1 mm, and the metal inner wall plate is used for supporting the metal dot matrix layer.

Furthermore, the high-strength heat-insulation metal dot matrix sandwich shell can bear the extrusion stress of 700-2000 MPa and can bear the impact of 5000-20000 g of acceleration.

Furthermore, the lattice unit cell is provided with a reinforcing rod in the direction perpendicular to the heat transfer direction to be connected with the lattice unit cell nodes, so that the transverse heat dissipation is further increased, and the damage caused by stress concentration at the lattice unit cell nodes is avoided.

Furthermore, the radius of the lattice unit cell rod is unchanged along the longitudinal heat transfer direction, and the side length l of the lattice unit cell, the radius r of the lattice unit cell rod and the heat transfer coefficient k of the metal material meet the requirements

Furthermore, the lattice unit cell is in a body-centered tetragonal structure, three side lengths a, b and c of the lattice unit cell, and the radius r of the lattice unit cell rod₁And r₂And the heat transfer coefficient k of the metal material satisfies the relationship

Further, the lattice unit cell has at least one of a tetrahedral type, a polyhedral type, a kagome type, and a diamond type.

Furthermore, the material of the metal lattice sandwich shell is at least one of aluminum alloy, titanium alloy, high-temperature alloy or steel.

According to a second aspect of the invention, a preparation method of a high-strength heat-insulation metal lattice sandwich shell is provided, which comprises the following steps:

step 1: constructing a three-dimensional model of the metal dot matrix sandwich shell;

step 2: slicing the three-dimensional model according to the layer thickness of 20-200 mu m by using layered slicing software;

and step 3: dividing the three-dimensional model after slicing into a filling path and a contour by using path planning software, and respectively carrying out forming path planning processing on the filling path and the contour to obtain a filling forming path and a contour forming path;

and 4, step 4: using metal powder, metal wires or metal blocks as raw materials, and sequentially performing single-layer printing and forming of the filling and the outline by using a 3D printing system of metal 3D printing equipment according to the filling forming path and the outline forming path, wherein the scanning interval of the single-layer printing and forming is 50-500 mu m, and the scanning speed is 10-1000 mm/s;

and 5: and (4) repeating the step (4) until the metal dot matrix sandwich shell is obtained after forming.

Further, the 3D printing system is at least one of a laser beam based 3D printing system, an electron beam based 3D printing system, an ion beam based 3D printing system, or a fluid flow fast cooling based 3D printing system.

Further, the metal outer wall plate of the high-strength heat-insulation metal dot matrix sandwich shell is subjected to strengthening heat treatment, and the metal dot matrix layer of the high-strength heat-insulation metal dot matrix sandwich shell is subjected to toughening treatment.

According to a third aspect of the present invention, there is provided a 3D printing system for a high strength thermal insulation metal dot matrix sandwich shell, the system comprising:

a processor and a memory for storing executable instructions;

wherein the processor is configured to execute the executable instructions to perform the method for preparing the high-strength heat-insulation metal lattice sandwich shell according to any one of the above aspects.

According to a third aspect of the present invention, there is provided a computer readable storage medium, on which a computer program is stored, wherein the computer program, when executed by a processor, implements the method for preparing a high strength thermal insulation metal lattice sandwich shell according to any one of the above aspects.

The invention has the beneficial effects that:

(1) according to the high-strength heat-insulation metal lattice sandwich shell, only one layer of complete metal body-centered cubic lattice unit cell is constructed in the longitudinal heat transfer direction, and the radius of a lattice unit cell rod in the longitudinal heat transfer direction is gradually reduced, so that the equivalent heat transfer coefficient of the metal lattice layer in the heat transfer direction is smaller than 0.1W/(m DEG C), the longitudinal heat transfer of the metal lattice layer is reduced, the transverse heat dissipation is increased, and the metal lattice sandwich shell has excellent heat insulation performance.

(2) The high-strength heat-insulation metal dot matrix sandwich shell fully utilizes the integral supporting and strengthening and toughening effects of the metal outer wall plate, and improves the strength and the shock resistance of the metal dot matrix sandwich shell by increasing the thickness of the metal outer wall plate; and the metal body-centered cubic lattice unit cells are perpendicular to the metal outer wall plate and are arranged in parallel, so that the metal lattice sandwich shell has the advantages of energy absorption, deformation buffering and the like.

(3) The high-strength heat-insulation metal lattice sandwich shell reduces the thickness of the metal inner wall plate, and reduces the radius of the lattice unit cell rod in the longitudinal heat transfer direction by increasing the lattice unit cell size of the metal lattice layer, so that the metal lattice sandwich shell has the advantage of light weight on the basis of high strength and heat insulation performance.

(4) The preparation method of the high-strength heat-insulation metal dot matrix sandwich shell provided by the invention adopts a metal 3D printing technology to carry out integrated printing and forming on the high-strength heat-insulation metal dot matrix sandwich shell, and has the characteristics of short production period, simple production process, low production cost, excellent shell comprehensive performance and the like.

Drawings

FIG. 1 is a schematic view of the high strength heat insulation metal lattice sandwich shell of the present invention.

FIG. 2 is a schematic cross-sectional and partially enlarged view of the high-strength heat-insulating metal lattice sandwich shell of the present invention. Wherein, 1 is a metal outer wall plate, 2 is a metal dot matrix layer, and 3 is a metal inner wall plate.

FIG. 3 is a schematic diagram of a metal-centered cubic lattice unit cell of the present invention. Wherein, 4 is lattice unit cell, 5 is lattice unit cell rod, and 6 is lattice unit cell node.

Fig. 4 is a partial metal dot matrix sandwich shell prepared by using a metal 3D printing technology in embodiment 3 of the present invention.

FIG. 5 is a temperature distribution diagram of a part of TB6 titanium alloy sandwich shell after flame combustion at 1200 ℃ for 30min is performed on an outer wall plate of the TB6 titanium alloy sandwich shell in example 3 of the invention.

FIG. 6 is a temperature distribution diagram of a part of TB6 titanium alloy solid shell after flame combustion is carried out for 2min at 1200 ℃ on the outer wall of the TB6 titanium alloy solid shell in comparative example 1 of the invention.

Detailed Description

The present invention is described in detail below with reference to the following examples, which are necessary to point out here only for further illustration of the present invention and should not be construed as limiting the scope of the present invention, and those skilled in the art can make some insubstantial modifications and adaptations to the present invention based on the above-mentioned disclosure.

The high-strength heat-insulation metal lattice sandwich shell is specifically described as follows by combining the attached drawings 1, 2 and 3:

the high-strength heat-insulation metal dot matrix sandwich shell comprises a metal outer wall plate 1, a metal dot matrix layer 2 and a metal inner wall plate 3. The thickness of the metal outer wall plate 1 is 3-10 mm, and the metal outer wall plate is used for improving the strength and the impact resistance of the high-strength heat-insulation metal dot matrix sandwich shell and bearing most of extrusion and impact energy; the thickness of the metal lattice layer 2 is 5-50 mm, the metal lattice layer is composed of metal body-centered cubic lattice unit cells 4 which are perpendicular to the metal outer wall plate 1 and are arranged in parallel, the side length l of each lattice unit cell 4 is the same as the thickness of the metal lattice layer 2, the radius of each lattice unit cell rod 5 is gradually reduced along the longitudinal heat transfer direction, and the radius r of the end, connected with the metal outer wall plate 1, of each lattice unit cell rod 5₁0.5-2.5 mm, radius r of the end where the lattice unit cell rod 5 is connected with the metal inner wall plate 3₂0.1-0.5 mm, the side length l of the lattice unit cell 4, and the radius r of the lattice unit cell rod 5₁And r₂And the heat transfer coefficient k of the metal material satisfiesThereby the longitudinal equivalent heat transfer coefficient of the metal lattice layer 2 is less than or equal to 0.1W/(m DEG C), and the transverse direction is increased while the longitudinal heat transfer of the metal lattice layer 2 is reducedThe heat dissipation is used for enabling the metal dot matrix layer 2 to have light weight, high strength and energy absorption effect and simultaneously have excellent heat insulation performance; the thickness of the metal inner wall plate 3 is 0.5-1 mm, and the metal inner wall plate is used for supporting the metal dot matrix layer 2.

Furthermore, the high-strength heat-insulation metal dot matrix sandwich shell can bear the extrusion stress of 700-2000 MPa and can bear the impact of 5000-20000 g of acceleration.

Furthermore, the lattice unit cell 4 is provided with a reinforcing rod in the direction perpendicular to the heat transfer direction to be connected with the lattice unit cell node 6, so that the transverse heat dissipation is further increased, and the lattice unit cell node 6 is prevented from being damaged due to stress concentration.

Furthermore, the radius of the lattice unit cell rod 5 is unchanged along the longitudinal heat transfer direction, and the side length l of the lattice unit cell 4, the radius r of the lattice unit cell rod 5 and the heat transfer coefficient k of the metal material meet the requirements

Furthermore, the lattice unit cell 4 is in a body-centered tetragonal structure, three side lengths a, b and c of the lattice unit cell 4 and the radius r of the lattice unit cell rod 5₁And r₂And the heat transfer coefficient k of the metal material satisfies the relationship

Further, the lattice unit cell 4 has at least one of a tetrahedral type, a polyhedral type, a kagome type, and a diamond type.

Furthermore, the material of the metal lattice sandwich shell is at least one of aluminum alloy, titanium alloy, high-temperature alloy or steel.

Example 1:

the thickness of the 316L stainless steel outer wall plate 1 of the 316L stainless steel dot matrix sandwich shell is 3 mm; the thickness of the 316L stainless steel lattice layer 2 is 20mm, the side length of the 316L stainless steel body-centered cubic lattice unit cell 4 is 20mm, and the radius r of the connecting end of the lattice unit cell rod 5 and the 316L stainless steel outer wall plate 1₁1mm, the radius r of the joint end of the lattice unit cell rod 5 and the 316L stainless steel inner wall plate 3₂Is 0.3mm, and the longitudinal equivalent heat transfer coefficient of the 316L stainless steel lattice layer 2 is 0.09W/(m DEG C); the thickness of the 316L stainless steel inner wall plate 3 is 0.5 mm. Constructing a three-dimensional model of a 316L stainless steel dot matrix sandwich shell; slicing the three-dimensional model according to the layer thickness of 30 mu m by using layered slicing software; dividing the three-dimensional model after slicing into a filling path and a contour by using path planning software, and respectively carrying out forming path planning processing on the filling path and the contour to obtain a filling forming path and a contour forming path; the method comprises the steps of taking 316L stainless steel powder with the radius of 20-50 mu m as a raw material, sequentially performing filling and outline single-layer printing forming according to a filling forming path and an outline forming path by using a laser 3D printing system of metal 3D printing equipment, wherein the scanning interval of the single-layer printing forming is 120 mu m, the scanning power is 500W, and the scanning speed is 800 mm/s; and repeating the steps until the 316L stainless steel dot matrix sandwich shell is obtained after forming. A test of 800 ℃ combustion simulation is carried out on the 316L stainless steel outer wall plate 1 of the 316L stainless steel dot matrix sandwich shell, and the temperature of the 316L stainless steel inner wall plate 3 of the 316L stainless steel dot matrix sandwich shell is 310 ℃ after 30min of combustion.

Example 2:

the 7075 aluminum alloy outer wall plate 1 of the 7075 aluminum alloy lattice sandwich shell is 5mm thick; the thickness of the 7075 aluminum alloy lattice layer 2 is 50mm, the side length of the 7075 aluminum alloy body-centered cubic lattice unit cell 4 is 50mm, and the radius r of the connecting end of the lattice unit cell rod 5 and the 7075 aluminum alloy outer wall plate 1₁0.8mm, the radius r of the connecting end of the lattice unit cell rod 5 and the 7075 aluminum alloy inner wall plate 3₂Is 0.1mm, the equivalent heat transfer coefficient of the 7075 aluminum alloy lattice layer 2 is 0.07W/(m DEG C); the thickness of the 7075 aluminum alloy inner wall plate 3 is 1 mm. Constructing a three-dimensional model of the 7075 aluminum alloy dot matrix sandwich shell; slicing the three-dimensional model according to the layer thickness of 20 mu m by using layered slicing software; dividing the three-dimensional model after slicing into a filling path and a contour by using path planning software, and respectively carrying out forming path planning processing on the filling path and the contour to obtain a filling forming path and a contour forming path; 7075 aluminum alloy powder with the radius of 10-40 mu m is used as a raw material, and a laser 3D printing system of metal 3D printing equipment is utilized according to the principleThe filling forming path and the outline forming path are sequentially subjected to single-layer printing forming of filling and outline, the scanning pitch of the single-layer printing forming is 60 mu m, the scanning power is 200W, and the scanning speed is 500 mm/s; and repeating the steps until the 7075 aluminum alloy dot matrix sandwich shell is obtained after forming. The 7075 aluminum alloy outer wall plate 1 of the 7075 aluminum alloy dot matrix sandwich shell is subjected to a 400 ℃ combustion simulation test, and the temperature of the 7075 aluminum alloy inner wall plate 3 of the 7075 aluminum alloy dot matrix sandwich shell is 90 ℃ after 30min combustion.

Example 3:

the thickness of the TB6 titanium alloy outer wall plate 1 of the TB6 titanium alloy lattice sandwich shell is 7 mm; the thickness of the TB6 titanium alloy lattice layer 2 is 10mm, the side length of the TB6 titanium alloy body-centered cubic lattice unit cell 4 is 10mm, the radius r of the lattice unit cell rod 5 is 0.2mm, and the equivalent heat transfer coefficient of the TB6 titanium alloy lattice layer 2 is 0.05W/(m DEG C); the thickness of the TB6 titanium alloy inner wall plate 3 is 1 mm. Constructing a three-dimensional model of the TB6 titanium alloy dot matrix sandwich shell; slicing the three-dimensional model according to the layer thickness of 30 mu m by using layered slicing software; dividing the three-dimensional model after slicing into a filling path and a contour by using path planning software, and respectively carrying out forming path planning processing on the filling path and the contour to obtain a filling forming path and a contour forming path; taking TB6 titanium alloy powder with the radius of 20-53 mu m as a raw material, and sequentially performing single-layer printing and forming of filling and outline by using a laser 3D printing system of metal 3D printing equipment according to the filling forming path and the outline forming path, wherein the scanning distance of the single-layer printing and forming is 70 mu m, the scanning power is 100W, and the scanning speed is 400 mm/s; and repeating the steps until forming to obtain the TB6 titanium alloy dot matrix sandwich shell, wherein part of the TB6 titanium alloy dot matrix sandwich shell is shown in figure 4. A1200 ℃ combustion simulation test is carried out on the TB6 titanium alloy outer wall plate 1 of the TB6 titanium alloy dot matrix sandwich shell, the temperature of the TB6 titanium alloy inner wall plate 3 of the TB6 titanium alloy dot matrix sandwich shell is 500 ℃ after 30min combustion, and the temperature distribution of part of the TB6 titanium alloy dot matrix sandwich shell is shown in figure 5.

Comparative example 1:

the thickness of the TB6 titanium alloy solid shell is 18mm, and the heat transfer coefficient is 16W/(m DEG C). Constructing a three-dimensional model of the TB6 titanium alloy solid shell; slicing the three-dimensional model according to the layer thickness of 30 mu m by using layered slicing software; dividing the three-dimensional model after slicing into a filling path and a contour by using path planning software, and respectively carrying out forming path planning processing on the filling path and the contour to obtain a filling forming path and a contour forming path; taking TB6 titanium alloy powder with the radius of 20-53 mu m as a raw material, and sequentially performing single-layer printing forming of filling and outline by using a laser 3D printing system of metal 3D printing equipment according to a filling forming path and an outline forming path, wherein the scanning pitch of the single-layer printing forming is 70 mu m, the scanning power is 100W, and the scanning speed is 400 mm/s; and repeating the steps until the TB6 titanium alloy solid shell is obtained through forming. The outer wall of the TB6 titanium alloy solid shell is subjected to 1200 ℃ combustion simulation test, the temperature of the inner wall of the TB6 titanium alloy solid shell is 1200 ℃ after 2min combustion, and the temperature distribution of part of the TB6 titanium alloy solid shell is shown in FIG. 6. .

The above-mentioned serial numbers of the embodiments of the present invention are merely for description and do not represent the merits of the embodiments.

Through the above description of the embodiments, those skilled in the art will clearly understand that the above implementation method can be implemented by software plus a necessary general hardware platform, and certainly, the implementation method can also be implemented by hardware only, but in many cases, the former is a better implementation method. Based on such understanding, the technical solution of the present invention or the portions contributing to the prior art may be essentially embodied in the form of a software product, which is stored in a storage medium (such as ROM/RAM, magnetic disk, optical disk) and includes instructions for enabling a terminal (such as a mobile phone, a computer, a server, or a network device) to execute the method according to the embodiments of the present invention.

While embodiments of the present invention have been described, the present invention is not limited to the above-described embodiments, which are intended to be illustrative rather than limiting, and many modifications may be made by those skilled in the art without departing from the spirit and scope of the invention as defined by the appended claims.