CN108705092B - 3D printing in-situ rare earth doped titanium-based composite material active bone implant and forming method - Google Patents

Abstract

Translated fromChinese

本发明公开3D打印原位稀土掺杂钛基复合材料活性骨植入体，包含原位稀土Re₂O₃、原位TiB陶瓷相及羟基磷灰石陶瓷相成形的原位稀土掺杂钛基复合材料。制备方法：将B₂O₃粉末与稀土Re粉末采用惰性气体保护的高能球磨工艺进行球磨混合，获得B₂O₃/Re混合粉末；称取B₂O₃/Re混合粉末、羟基磷灰石粉末、3D打印专用球形钛合金粉末，惰性气体辅助保护的低能球磨工艺，获得钛合金复合材料粉末；氩气环境下，利用激光3D打印成形原位稀土Re₂O₃、原位TiB陶瓷及羟基磷灰石陶瓷增强的钛基复合材料活性骨植入体。本方法通过稀土原位掺杂提升钛合金骨植入体的服役性能，可实现高性能复杂结构钛合金活性骨植入体的精密制造。

The invention discloses a 3D printing in-situ rare earth-doped titanium-based composite active bone implant, which comprises an in-situ rare-earth-doped titanium base formed by in-situ rare earth Re₂ O₃ , an in-situ TiB ceramic phase and a hydroxyapatite ceramic phase. composite material. Preparation method: B₂ O₃ powder and rare earth Re powder are ball-milled and mixed by high-energy ball milling process protected by inert gas to obtain B₂ O₃ /Re mixed powder; Weigh B₂ O₃ /Re mixed powder, hydroxyapatite Powder, 3D printing special spherical titanium alloy powder, inert gas-assisted low-energy ball milling process to obtain titanium alloy composite powder; in argon environment, laser 3D printing is used to form in-situ rare earth Re₂ O₃ , in-situ TiB ceramics and hydroxyl groups Apatite ceramic-reinforced titanium-matrix composite active bone implants. The method improves the service performance of the titanium alloy bone implant by in-situ doping of rare earth, and can realize the precise manufacture of the high-performance complex structure titanium alloy active bone implant.

Description

3D printing in-situ rare earth doped titanium-based composite material active bone implant and forming method

Technical Field

The invention belongs to the field of medical instrument manufacturing, relates to a novel titanium alloy active bone implant and a forming method, and particularly relates to a 3D printing in-situ rare earth doping reinforced titanium-based composite active bone implant and a forming method.

Background

In recent years, the repair and replacement of bone tissue defects are rapidly increased due to the increasing of human tissue loss or dysfunction caused by the aging of social population, traffic accidents and the like in China. Compared with medical metal materials such as stainless steel, cobalt-chromium alloy and the like, the titanium alloy has the advantages of better mechanical property, good corrosion resistance, excellent biocompatibility and the like, and becomes an ideal metal material for clinically applied artificial bone implants. The ideal biomedical implant material has good biomechanical compatibility, namely the strength and the density of the implant material are close to those of self tissues, meanwhile, the implant material has good biocompatibility, has no rejection reaction with the original tissues, has excellent bioactivity, and can promote and induce the attachment and the growth of new bones. However, titanium alloy is an inert material, the bioactivity of titanium alloy is not ideal enough, the growth of new bone and the differentiation of osteoblast cannot be promoted, and the titanium alloy and human bone tissue are only mechanically embedded and connected, and the growth of human defect bone tissue cannot be induced. The hydroxyapatite is the main component of human skeleton, has good biocompatibility and activity, can be combined with human bone tissue and induce the growth and formation of new bone, and is an ideal hard tissue substitute material. The titanium/hydroxyapatite composite material prepared by the Wang moon et al through powder sintering can obviously improve the bioactivity of the titanium alloy bone implant.

However, hydroxyapatite is unstable at high temperature and has poor sintering property with titanium alloy powder, resulting in a decrease in fracture toughness and strength, and thus being limitedMaking its application in bearing site bone replacement. The rare earth oxide can be used as the core of nucleation because the tiny solid particles can increase the solidification and nucleation rate and enhance the effect of refining grains, thereby being widely used for improving and enhancing the mechanical property of hydroxyapatite materials. In the prior art, rare earth oxide is mainly added into hydroxyapatite and a composite material coating thereof by a direct addition method so as to improve the performance of titanium alloy and hydroxyapatite. For example, Zhang Asia et al found a small amount of Y₂O₃The stability of the hydroxyapatite structure can be increased. Liu bin etc. to transform Y₂O₃、CeO₂、La₂O₃And the rare earth oxide is directly added into the hydroxyapatite coating to obtain good biological activity and osteogenic property. Therefore, the rare earth oxide can improve the forming performance of the hydroxyapatite and enhance the biological activity of the hydroxyapatite, and is a good reinforcing agent.

At present, the prior direct addition method has the following defects: (1) because the rare earth oxide belongs to a ceramic material, the rare earth oxide is difficult to promote to form a good metallurgical bonding interface with matrix titanium alloy and hydroxyapatite, so that the mechanical property of the rare earth oxide is reduced; (2) the space structure of the titanium alloy artificial bone implant is greatly different due to the age, sex and disease condition difference of patients, meanwhile, the space structure of the artificial bone implant is very complex, especially for hip joints, knee joints and the like, and the traditional process method is difficult to realize the precise manufacture of the rare earth reinforced titanium alloy active implant.

Disclosure of Invention

The purpose of the invention is as follows: the invention provides a 3D printing in-situ rare earth doping reinforced titanium-based composite active bone implant and a forming method of the 3D printing in-situ rare earth doping reinforced titanium-based composite active bone implant, aiming at the problems of the existing rare earth reinforced artificial titanium alloy active implant.

The laser 3D printing method is a manufacturing mode of channel-by-channel and layer-by-layer based on the principle of additive manufacturing, can disperse a complex structural member into a series of thin two-dimensional sections (the thickness is usually less than 100 mu m), and realizes the precise manufacturing. Compared with the traditional process method, the laser 3D printing has the characteristics of intellectualization, no modeling and flexible manufacturing, the utilization rate of materials is improved, the follow-up complex post-processing process is not needed, and the manufacturing period is short. The process method provides an effective way for the precise manufacture of the titanium alloy artificial bone implant with a complex structure.

The technical scheme is as follows: the 3D printing in-situ rare earth doped titanium-based composite active bone implant comprises in-situ rare earth Re₂O₃In-situ rare earth doped titanium-based composite material formed by in-situ TiB ceramic phase and hydroxyapatite ceramic phase. The implant is in-situ rare earth Re₂O₃An in-situ TiB ceramic phase and a hydroxyapatite ceramic phase.

Preferably, the in-situ rare earth Re₂O₃And in-situ TiB ceramic phase passing through B₂O₃The powder, the Re powder and the special spherical titanium alloy powder for 3D printing are subjected to 2Ti + B treatment under the action of a high-energy laser beam of 250-450J/m₂O₃+2Re→2TiB+Re₂O₃Formed by in situ reaction.

The invention relates to a forming method of a 3D printing in-situ rare earth doped titanium-based composite active bone implant, which comprises the following steps:

(1) mixing a certain mass ratio of B₂O₃Ball-milling and mixing the powder and the rare earth Re powder by adopting a high-energy ball-milling process under the protection of argon and at the rotating speed of 250-400 rpm to obtain metallurgically bonded B₂O₃A Re mixed powder;

(2) weighing B in a certain mass ratio₂O₃The preparation method comprises the following steps of (1) obtaining titanium alloy composite material powder with good fluidity by adopting a ball-free wet low-energy ball milling process with the rotation speed of 50-150 rpm under the auxiliary protection of argon gas, wherein the ball-free wet low-energy ball milling process is used for the/Re mixed powder, the hydroxyapatite powder and the special spherical titanium alloy powder for 3D printing;

(3) forming in-situ rare earth Re by utilizing a laser 3D printing process in a high-purity argon environment₂O₃The titanium-based composite material active bone implant reinforced by the in-situ TiB ceramic phase and the hydroxyapatite ceramic phase.

Among them, in the above step (1), it is preferable to useB₂O₃The purity of the powder is better than 99.5%, the particle size is 1-30 mu m, the purity of the rare earth Re powder is better than 99.0%, the particle size is 1-30 mu m, and the rare earth Re is one of Nd, Ce and La;

further, B is₂O₃The mass ratio of the powder to the rare earth Re powder is 1: 2-1: 5.

Preferably, in the step (2), the spherical titanium alloy is pure Ti, Ti-Ni, Ti-Zr or Ti-Al;

further, B is₂O₃The mass ratio of the/Re mixed powder to the hydroxyapatite powder to the spherical titanium alloy powder special for 3D printing is 5:1: 20-2: 1: 500.

Further, in the step (3), the laser 3D printing forming process conditions are preferably: under the action of a high-energy laser beam with the laser energy density of 250-450J/m, a partition scanning mode is adopted, and the size of each partition is 1 multiplied by 1-8 multiplied by 8mm²The stacking fault increment is 30-45 degrees.

The invention principle is as follows: the forming method of the 3D printing in-situ rare earth doping titanium-based composite material active bone implant takes the improvement of the interface characteristic of hydroxyapatite and rare earth oxide in the artificial titanium alloy active bone implant and the precise manufacture of the artificial titanium alloy active bone implant with a functional complex structure as a foothold, and is based on the rapid non-equilibrium melting/solidification characteristic of multi-field coupling of laser 3D printing, high-energy laser and titanium alloy/B₂O₃In-situ reaction thermodynamic conditions among rare earth elements, a precise forming geometric structure is more complex, and the active bone implant is provided with an in-situ rare earth doped titanium-based composite material.

Has the advantages that: compared with the prior art, the invention has the beneficial effects that:

(1) the 3D-printed in-situ rare earth-doped titanium-based composite active bone implant disclosed by the invention has the characteristic that the bioactivity of hydroxyapatite can be remarkably improved based on rare earth oxide according to high-energy laser and titanium alloy/B₂O₃In-situ reaction thermodynamic conditions among rare earth elements, a laser 3D printing technology is adopted to form a rare earth oxide/hydroxyapatite interface with metallurgical bonding characteristics, and comprehensive clothes of the titanium alloy active bone implant are obviously enhancedService performance; on the other hand, the rare earth oxide generated in situ provides nucleation particles for the solidification of the titanium-based composite material, further refines the solidification tissue of the titanium-based composite material, and effectively improves the comprehensive mechanical property of the active bone implant of the titanium-based composite material.

(2) The 3D printing in-situ rare earth doped titanium-based composite active bone implant is based on 2Ti + B₂O₃+2Re→2TiB+Re₂O₃The TiB ceramic phase formed by the in-situ reaction also has a good strengthening function, and can effectively improve the mechanical property of the titanium-based composite material active bone implant; meanwhile, the rapid nonequilibrium melting/solidification characteristic of laser 3D printing multi-field coupling is easy to cause large temperature gradient, high solidification speed and the like in the forming process of the titanium-based composite material, so that the solidification structure is fine, and the fine grain strengthening effect is obvious.

(3) The forming method provided by the invention is based on the forming performance and the biological activity of the hydroxyapatite, the biological characteristics of the rare earth oxide and 2Ti + B₂O₃+2Re→2TiB+Re₂O₃In-situ reaction thermodynamic conditions and non-equilibrium forming characteristics of laser 3D printing multi-field coupling are adopted, the active bone implant made of the in-situ rare earth doped titanium-based composite material is formed by utilizing a laser 3D printing technology, and the integrated manufacturing of the artificial titanium alloy active bone implant with the high-performance complex structure is realized.

Drawings

Fig. 1 is a microstructure topography of the 3D printed in situ rare earth doped titanium matrix composite active bone implant prepared in example 1.

Fig. 2 is a graph of the room temperature tensile strength of the 3D printed in-situ rare earth doped titanium-based composite active bone implant prepared in example 2.

Fig. 3 is a fracture morphology diagram of the 3D-printed in-situ rare earth-doped titanium-based composite active bone implant prepared in example 3.

Fig. 4 is a graph of fracture toughness of the 3D-printed in-situ rare earth-doped titanium-based composite active bone implant prepared in examples 4 to 6.

Detailed Description

The technical scheme of the invention is further explained by combining the attached drawings.

The invention relates to an active bone implant made of in-situ rare earth doped titanium-based composite material through 3D printing, which is an in-situ rare earth Re₂O₃Phase, in-situ TiB ceramic phase and hydroxyapatite ceramic phase reinforced active titanium alloy matrix; wherein, in-situ rare earth Re₂O₃Phase and in situ TiB ceramic phase passing through B₂O₃The powder, the Re powder and the special spherical titanium alloy powder for 3D printing are synthesized in situ under the action of high-energy laser beams.

The invention is based on the forming performance and the biological activity of the hydroxyapatite, the biological characteristics of the rare earth oxide, 2Ti + B₂O₃+2Re→2TiB+Re₂O₃In-situ reaction thermodynamic conditions and non-equilibrium forming characteristics of laser 3D printing multi-field coupling, by means of a laser 3D printing technology, an in-situ rare earth doped titanium-based composite material active bone implant with a metallurgical bonding characteristic, a rare earth oxide/hydroxyapatite interface, tissue refinement and a complex structure is formed, and the comprehensive service performance of the titanium alloy active bone implant can be remarkably improved.

The following examples all use commercially available B₂O₃The purity of the powder is better than 99.5%, the particle size is 1-30 mu m, the purity of the rare earth Re powder is better than 99.0%, the particle size is 1-30 mu m, and hydroxyapatite powder is used as an experimental raw material.

Example 1

(1) B with the mass ratio of 1:2₂O₃Ball-milling and mixing the powder and the rare earth Nd powder by adopting a high-energy ball-milling process with the rotation speed of 250rpm under the protection of argon gas to obtain B with metallurgical bonding₂O₃a/Nd mixed powder;

(2) weighing B with the mass ratio of 5:1:20₂O₃The preparation method comprises the following steps of (1) obtaining titanium alloy composite material powder with good fluidity by adopting a ball-free wet low-energy ball milling process with the rotation speed of 50rpm under the auxiliary protection of argon gas, wherein the ball-free wet low-energy ball milling process comprises the following steps of mixing Nd mixed powder, hydroxyapatite powder and special spherical pure Ti powder for 3D printing;

(3) under the protection of high-purity argon, a laser 3D printing process is utilized, and the partition size is set to be 1 multiplied by 1mm²The stacking fault increment is 30 degrees, and the 3D printing in-situ rare earth in-situ doping is formed by adopting the laser energy density of 250J/mA hybrid reinforced titanium-based composite active bone implant.

FIG. 1 is a microstructure topography of a 3D printed in situ rare earth doped titanium matrix composite active bone implant made in example 1, from which Nd can be found₂O₃The rare earth oxide phase, the hydroxyapatite phase and the titanium alloy matrix have good interface bonding without obvious gaps and cracks, and meanwhile, the small-size white point-shaped particles are TiB ceramic phase and are uniformly dispersed on the titanium alloy bone implant matrix.

Example 2

A 3D printed in situ rare earth in situ doped reinforced titanium matrix composite active bone implant made with reference to the forming method of example 1, except that: in the step (1) of the embodiment, the rotation speed of the high-energy ball mill is adjusted to 300 rpm; in the step (2), the ball-free wet low-energy rotating speed is set to be 100rpm, and B₂O₃The mass ratio of the/Nd mixed powder to the hydroxyapatite powder to the spherical pure Ti powder special for 3D printing is set to be 3:1: 25; adjusting the size of the laser scanning subarea in the step (3) to be 4 multiplied by 4mm²The laser fluence was adjusted to 300J/m.

Fig. 2 is a graph of the tensile strength at room temperature of the 3D-printed in-situ rare earth-doped titanium-based composite active bone implant prepared in example 2, and it can be found that the strength of the rare earth-doped titanium-based composite active bone implant reaches 1102.50MPa, and the elongation reaches 19.04%, which indicates that the strength and the plasticity of the active bone implant are both significantly improved and are much higher than the strength (860.10MPa) and the elongation (8.05%) of the existing Ti/HA composite.

Example 3

A 3D printed in situ rare earth in situ doped reinforced titanium matrix composite active bone implant made with reference to the forming method of example 2, except that: in this example, in step (1), the rare earth element was Ce and B₂O₃Adjusting the mass ratio of the powder to the rare earth Ce powder to be 1:3, and adjusting the rotating speed of the high-energy ball mill to be 400 rpm; setting the titanium alloy in the step (2) as a Ti-Ni alloy; adjusting the size of the laser scanning subarea in the step (3) to be 5 multiplied by 5mm²The stacking fault increment was 35 °.

Fig. 3 is a fracture morphology diagram of the 3D-printed in-situ rare earth-doped titanium-based composite active bone implant prepared in example 3, and it is obvious that tensile fracture morphologies are all tough-fossilized, which indicates that the in-situ rare earth oxide and TiB ceramic phase significantly improve the mechanical properties of the hydroxyapatite/titanium alloy composite.

Example 4

A 3D printed in situ rare earth in situ doped reinforced titanium matrix composite active bone implant made with reference to the forming method of example 3, except that: this example, step (1) was carried out by selecting La as the rare earth element and B as the rare earth element₂O₃The mass ratio of the powder to the rare earth La powder is adjusted to 1: 5; setting the ball-free wet low-energy rotating speed to be 150rpm in the step (2), setting the titanium alloy to be Ti-Zr alloy, and setting B₂O₃The mass ratio of the/La mixed powder to the hydroxyapatite powder to the spherical Ti-Zr alloy powder special for 3D printing is set to be 5:1: 20.

Example 5

A 3D printed in situ rare earth in situ doped reinforced titanium matrix composite active bone implant made with reference to the forming method of example 4, except that: in the step (1) of the embodiment, the high-energy ball milling speed is adjusted to 350 rpm; setting the ball-free wet low-energy rotating speed to be 120rpm in the step (2), selecting the rare earth element to be Nd, and setting B in the step (2)₂O₃The mass ratio of the/Nd mixed powder to the hydroxyapatite powder to the spherical Ti-Zr alloy powder special for 3D printing is set to be 3:1: 250; adjusting the size of the laser scanning subarea in the step (3) to 8 multiplied by 8mm²。

Example 6

A 3D printed in situ rare earth in situ doped reinforced titanium matrix composite active bone implant made with reference to the forming method of example 5, except that: in the step (1) of this example, the titanium alloy was set to be a Ti-Al alloy; in the step (2), B is added₂O₃The mass ratio of the Re mixed powder to the hydroxyapatite powder to the spherical titanium alloy powder special for 3D printing is adjusted to be 2:1: 500; and (4) setting the increment of the laser scanning stacking fault in the step (3) to be 45 degrees, and setting the laser energy density to be 450J/m.

FIG. 4 is a graph of fracture toughness of the 3D-printed in-situ rare earth-doped titanium-based composite active bone implant prepared in examples 4 to 6, and it can be found that the fracture toughness is 6.62MPa respectively/m²、8.15MPa/m²And 9.98MPa/m²The fracture toughness (3.5 MPa/m) of the composite material is obviously higher than that of the existing Ti/HA composite material²) Therefore, the 3D printing in-situ rare earth doped titanium-based composite active bone implant provided by the invention can obviously improve the metallurgical characteristics of the composite interface and can also improve the comprehensive mechanical properties of the implant, such as strength, toughness and the like.

Claims (9)

Translated fromChinese

1.一种3D打印原位稀土掺杂钛基复合材料活性骨植入体，其特征在于，所述植入体包括原位稀土Re₂O₃、原位TiB陶瓷相及羟基磷灰石陶瓷相成形的原位稀土掺杂钛基复合材料，所述原位稀土Re₂O₃及原位TiB陶瓷相通过B₂O₃粉末、Re粉末及3D打印专用球形钛合金粉末在激光能量密度为250～450 J/m的高能激光束作用下原位合成，所述3D打印原位稀土掺杂钛基复合材料活性骨植入体的成形方法包括下述步骤：1. A 3D printing in-situ rare earth-doped titanium-based composite active bone implant, characterized in that the implant comprises in-situ rare earth Re₂ O₃ , in-situ TiB ceramic phase and hydroxyapatite ceramics Phase-shaped in-situ rare earth-doped titanium-based composite material, the in-situ rare earth Re₂ O₃ and in-situ TiB ceramic phases are produced by B₂ O₃ powder, Re powder and spherical titanium alloy powder for 3D printing. The laser energy density is In-situ synthesis under the action of a high-energy laser beam of 250-450 J/m, the forming method of the 3D printing in-situ rare earth-doped titanium-based composite active bone implant includes the following steps:（1）将一定重量比的B₂O₃粉末与稀土Re粉末采用氩气保护的转速为250～400 rpm的高能球磨工艺进行球磨混合，获得具有冶金结合的B₂O₃/Re混合粉末；(1) Ball milling and mixing a certain weight ratio of B₂ O₃ powder and rare earth Re powder using a high-energy ball milling process with a rotational speed of 250-400 rpm under argon protection to obtain a B₂ O₃ /Re mixed powder with metallurgical bonding;（2）称取一定质量比的B₂O₃/Re混合粉末、羟基磷灰石粉末、3D打印专用球形钛合金粉末，采用氩气辅助保护的转速50～150 rpm的无球湿式低能球磨工艺，获得钛合金复合材料粉末；(2) Weigh a certain mass ratio of B₂ O₃ /Re mixed powder, hydroxyapatite powder, and spherical titanium alloy powder for 3D printing, and use argon-assisted protection with a ball-free wet low-energy ball milling process at a speed of 50-150 rpm , to obtain titanium alloy composite powder;（3）在高纯氩气环境下，利用激光3D打印工艺，成形钛合金复合材料粉末，获得原位稀土Re₂O₃、原位TiB陶瓷相及羟基磷灰石陶瓷相增强的钛基复合材料活性骨植入体。(3) In a high-purity argon atmosphere, using a laser 3D printing process, the titanium alloy composite powder is formed to obtain an in-situ rare earth Re₂ O₃ , an in-situ TiB ceramic phase and a hydroxyapatite ceramic phase reinforced titanium matrix composite. Materials Active Bone Implant.2.一种权利要求1所述的3D打印原位稀土掺杂钛基复合材料活性骨植入体的成形方法，其特征在于，包括下述步骤：2. A method for forming a 3D printing in-situ rare earth-doped titanium-based composite active bone implant according to claim 1, characterized in that, comprising the following steps:（1）将一定重量比的B₂O₃粉末与稀土Re粉末采用氩气保护的转速为250～400 rpm的高能球磨工艺进行球磨混合，获得具有冶金结合的B₂O₃/Re混合粉末；(1) Ball milling and mixing a certain weight ratio of B₂ O₃ powder and rare earth Re powder using a high-energy ball milling process with a rotational speed of 250-400 rpm under argon protection to obtain a B₂ O₃ /Re mixed powder with metallurgical bonding;（2）称取一定质量比的B₂O₃/Re混合粉末、羟基磷灰石粉末、3D打印专用球形钛合金粉末，采用氩气辅助保护的转速50～150 rpm的无球湿式低能球磨工艺，获得钛合金复合材料粉末；(2) Weigh a certain mass ratio of B₂ O₃ /Re mixed powder, hydroxyapatite powder, and spherical titanium alloy powder for 3D printing, and use argon-assisted protection with a ball-free wet low-energy ball milling process at a speed of 50-150 rpm , to obtain titanium alloy composite powder;（3）在高纯氩气环境下，利用激光3D打印工艺，成形钛合金复合材料粉末，获得原位稀土Re₂O₃、原位TiB陶瓷相及羟基磷灰石陶瓷相增强的钛基复合材料活性骨植入体。(3) In a high-purity argon atmosphere, using a laser 3D printing process, the titanium alloy composite powder is formed to obtain an in-situ rare earth Re₂ O₃ , an in-situ TiB ceramic phase and a hydroxyapatite ceramic phase reinforced titanium matrix composite. Materials Active Bone Implant.3.根据权利要求2所述的3D打印原位稀土掺杂钛基复合材料活性骨植入体的成形方法，其特征在于，步骤（1）中，所述B₂O₃粉末纯度优于99.5%，粒径为1～30 μm。3 . The method for forming a 3D printed in-situ rare earth-doped titanium-based composite active bone implant according to claim 2 , wherein in step (1), the purity of the B₂ O₃ powder is better than 99.5 %, the particle size is 1-30 μm.4.根据权利要求2所述的3D打印原位稀土掺杂钛基复合材料活性骨植入体的成形方法，其特征在于，步骤（1）中，所述稀土Re粉末纯度优于99.0%，粒径为1～30 μm。4. The method for forming a 3D printed in-situ rare earth-doped titanium-based composite active bone implant according to claim 2, wherein in step (1), the purity of the rare earth Re powder is better than 99.0%, The particle size is 1 to 30 μm.5.根据权利要求2所述的3D打印原位稀土掺杂钛基复合材料活性骨植入体的成形方法，其特征在于，步骤（1）中，所述稀土Re为Nd、Ce、La中的一种。5 . The method for forming a 3D printed in-situ rare earth-doped titanium-based composite active bone implant according to claim 2 , wherein in step (1), the rare earth Re is among Nd, Ce, and La. 6 . a kind of.6.根据权利要求2所述的3D打印原位稀土掺杂钛基复合材料活性骨植入体的成形方法，其特征在于，步骤（1）中，所述B₂O₃粉末与稀土Re粉末质量比为1:2 ～1:5。6 . The method for forming a 3D printed in-situ rare earth-doped titanium-based composite active bone implant according to claim 2 , wherein in step (1), the B₂ O₃ powder and the rare earth Re powder are mixed together. 7 . The mass ratio is 1:2 to 1:5.7.根据权利要求2所述的3D打印原位稀土掺杂钛基复合材料活性骨植入体的成形方法，其特征在于，步骤（2）中，所述球形钛合金为纯Ti、Ti-Ni、Ti-Zr或Ti-Al中的一种。7 . The method for forming a 3D printed in-situ rare earth-doped titanium-based composite active bone implant according to claim 2 , wherein in step (2), the spherical titanium alloy is pure Ti, Ti- One of Ni, Ti-Zr or Ti-Al.8.根据权利要求2所述的3D打印原位稀土掺杂钛基复合材料活性骨植入体的成形方法，其特征在于，步骤（2）中，所述B₂O₃/Re混合粉末、羟基磷灰石粉末、3D打印专用球形钛合金粉末质量比为5:1:20～2:1:500。8 . The method for forming a 3D printed in-situ rare earth-doped titanium-based composite active bone implant according to claim 2 , wherein in step (2), the B₂ O₃ /Re mixed powder, The mass ratio of hydroxyapatite powder and spherical titanium alloy powder for 3D printing is 5:1:20～2:1:500.9.根据权利要求2所述的3D打印原位稀土掺杂钛基复合材料活性骨植入体的成形方法，其特征在于，步骤（3）中，所述激光3D打印成形工艺采用激光能量密度为250～450 J/m的高能激光束作用下，采用分区扫描方式，分区大小为1×1～8×8 mm²，层错增量为30°～45°。9 . The method for forming a 3D printing in-situ rare earth-doped titanium-based composite active bone implant according to claim 2 , wherein, in step (3), the laser 3D printing forming process adopts laser energy density. 10 . Under the action of a high-energy laser beam of 250-450 J/m, the partition scanning method is adopted, the partition size is 1×1-8×8 mm² , and the stacking fault increment is 30°-45°.

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