CN111702278B - Ti2Medium-temperature Ti-based brazing filler metal for brazing same or different AlNb-based alloys as well as preparation method and brazing process thereof - Google Patents

Ti2Medium-temperature Ti-based brazing filler metal for brazing same or different AlNb-based alloys as well as preparation method and brazing process thereof Download PDF

Info

Publication number
CN111702278B
CN111702278B CN202010403203.0A CN202010403203A CN111702278B CN 111702278 B CN111702278 B CN 111702278B CN 202010403203 A CN202010403203 A CN 202010403203A CN 111702278 B CN111702278 B CN 111702278B
Authority
CN
China
Prior art keywords
brazing
elements
filler metal
brazing filler
alloy
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
CN202010403203.0A
Other languages
Chinese (zh)
Other versions
CN111702278A (en
Inventor
蔡雨升
王清江
杨锐
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Institute of Metal Research of CAS
Original Assignee
Institute of Metal Research of CAS
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Institute of Metal Research of CAS filed Critical Institute of Metal Research of CAS
Priority to CN202010403203.0A priority Critical patent/CN111702278B/en
Publication of CN111702278A publication Critical patent/CN111702278A/en
Application granted granted Critical
Publication of CN111702278B publication Critical patent/CN111702278B/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23KSOLDERING OR UNSOLDERING; WELDING; CLADDING OR PLATING BY SOLDERING OR WELDING; CUTTING BY APPLYING HEAT LOCALLY, e.g. FLAME CUTTING; WORKING BY LASER BEAM
    • B23K35/00Rods, electrodes, materials, or media, for use in soldering, welding, or cutting
    • B23K35/22Rods, electrodes, materials, or media, for use in soldering, welding, or cutting characterised by the composition or nature of the material
    • B23K35/24Selection of soldering or welding materials proper
    • B23K35/32Selection of soldering or welding materials proper with the principal constituent melting at more than 1550 degrees C
    • B23K35/325Ti as the principal constituent
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23KSOLDERING OR UNSOLDERING; WELDING; CLADDING OR PLATING BY SOLDERING OR WELDING; CUTTING BY APPLYING HEAT LOCALLY, e.g. FLAME CUTTING; WORKING BY LASER BEAM
    • B23K1/00Soldering, e.g. brazing, or unsoldering
    • B23K1/002Soldering by means of induction heating
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23KSOLDERING OR UNSOLDERING; WELDING; CLADDING OR PLATING BY SOLDERING OR WELDING; CUTTING BY APPLYING HEAT LOCALLY, e.g. FLAME CUTTING; WORKING BY LASER BEAM
    • B23K1/00Soldering, e.g. brazing, or unsoldering
    • B23K1/008Soldering within a furnace
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23KSOLDERING OR UNSOLDERING; WELDING; CLADDING OR PLATING BY SOLDERING OR WELDING; CUTTING BY APPLYING HEAT LOCALLY, e.g. FLAME CUTTING; WORKING BY LASER BEAM
    • B23K3/00Tools, devices, or special appurtenances for soldering, e.g. brazing, or unsoldering, not specially adapted for particular methods
    • B23K3/08Auxiliary devices therefor
    • B23K3/087Soldering or brazing jigs, fixtures or clamping means
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B23MACHINE TOOLS; METAL-WORKING NOT OTHERWISE PROVIDED FOR
    • B23KSOLDERING OR UNSOLDERING; WELDING; CLADDING OR PLATING BY SOLDERING OR WELDING; CUTTING BY APPLYING HEAT LOCALLY, e.g. FLAME CUTTING; WORKING BY LASER BEAM
    • B23K2103/00Materials to be soldered, welded or cut
    • B23K2103/18Dissimilar materials
    • B23K2103/24Ferrous alloys and titanium or alloys thereof

Abstract

The invention belongs to the field of welding, and particularly relates to Ti2An AlNb-based alloy same-material or different-material brazing medium-temperature Ti-based brazing filler metal, and a preparation method and a brazing process thereof. The brazing filler metal comprises the following components in percentage by weight: 15 to 40 percent of Ni, 1 to 15 percent of Co or 1 to 15 percent of Mo, less than or equal to 5 percent of one or more than two of a small amount of elements of Al, B, Fe, Cu, Cr, Mn, Mg, Ag, Nb and Zn, less than or equal to 2 percent of one or more than two of trace elements of Zr, Hf, V, Ta, W, Au, Si, Sn, Pd and Ga, and the balance of Ti and inevitable impurity elements. The preparation method of the brazing filler metal comprises the following steps: firstly, weighing raw materials; secondly, smelting a brazing filler metal master alloy; thirdly, carrying out quenching and strip throwing on the smelted mother alloy to obtain the brazing filler metal. The brazing filler metal is brazed according to a brazing process of 980-1040 ℃ and 0-120 min. Compared with the existing solder, the solder prepared by the invention has the advantages of proper melting point, excellent wettability and high-temperature mechanical property, and simple preparation and soldering processes.

Description

Ti2Medium-temperature Ti-based brazing filler metal for brazing same or different AlNb-based alloys as well as preparation method and brazing process thereof
Technical Field
The invention belongs to the field of welding, and particularly relates to Ti2An AlNb-based alloy same-material or different-material brazing medium-temperature Ti-based brazing filler metal, and a preparation method and a brazing process thereof.
Background
As is well known, the engine is used as the heart of various aircrafts, and the development degree of aviation and aerospace engine materials is the most limited. Because the service conditions of engines in the fields of aviation and aerospace are harsh, the materials are required to have excellent room temperature performance and excellent high temperature performance. At the same time, the material also has good processing performance and high specific strength so as to facilitate the processing of parts and reduce the specific gravity of the component.
The nickel-based high-temperature alloy has high specific strength, good oxidation resistance, excellent hot corrosion resistance and good fatigue resistance, and is used as a material of parts of aviation and aerospace engines from the beginning. However, due to its high density and use temperature, it does not meet the requirements of advanced aircraft enginesAnd limits the wide application of the nickel-based superalloy. The Ti-Al intermetallic compound is used as a mesophase compound, and has the advantages of low density, high elastic modulus, good high-temperature strength, creep resistance, oxidation resistance and the like, so that the Ti-Al intermetallic compound becomes a novel high-temperature light material with wide application prospect in the fields of aviation and aerospace. However, α2-Ti3Al-based alloys and γ -Ti Al-based alloys have poor room temperature formability and thermoplastic deformability, although they have high specific strength and low density. The students are on Ti3In the toughening research process of the Al-based alloy, a beta stabilizing element Nb is added to further discover Ti2AlNb-based alloy (i.e., O-phase alloy) which is a typical Ti-Al based intermetallic compound having a D019 structure2-Ti3Al and gamma-Ti Al of the structure L10. The intermetallic compound with the orthogonal structure has the characteristics of high specific strength and specific stiffness, high-temperature creep resistance and fracture toughness, good oxidation resistance, low thermal expansion coefficient and the like, the use temperature can reach 700 ℃, the intermetallic compound is superior to nickel-based high-temperature alloy, can replace the nickel-based high-temperature alloy to realize the weight reduction effect, and the weight of the same part is reduced by nearly 40 percent compared with the weight of the nickel-based alloy. These excellent properties of Ti2AlNb-based alloys have become the most promising light weight, high temperature structural materials and have begun to enter the use stage in the aerospace field.
At Ti2The AlNb-based alloy inevitably involves connection problems with itself or other alloys during use. From the current published paper situation at home and abroad, Ti2The connection technology of AlNb-based alloys is mainly classified into fusion welding (e.g., arc welding, laser welding, and electron beam welding), and solid state welding (e.g., diffusion welding, self-propagating high-temperature synthesis, and friction welding), which have problems that are difficult to overcome. Compared with the prior art, the brazing method has the advantages of low brazing temperature, small influence on the base metal, small joint residual stress, capability of selecting various filling metals according to the requirements of the connection temperature and the joint strength, and suitability for connecting difficult-to-melt metals and dissimilar metals. Therefore, the brazing method is adopted for Ti2The AlNb-based alloy has good prospect for connection.
Solder is one of the important factors affecting the performance of soldered joints, and at present, soldering Ti2The brazing filler metal of AlNb-based alloys is mainly of 3 types, i.e., silver-based, aluminum-based, titanium-based or titanium-zirconium-based. The Ag-based solder has a proper melting point, but the Ag-based solder is sensitive to chloride ions, so that the corrosion resistance of a soldered joint is poor, and the strength of the soldered joint is low. While the Al-based brazing filler metal is used for brazing Ti2In the case of AlNb-based alloys, a large amount of brittle intermetallic compound phases are formed at the joint, so that the joint brittleness increases, and the fatigue properties and impact strength are low. In addition, the Ag-based and Al-based solders have low melting points and thus the use temperatures of the materials after brazing are low. Compared with Ag-based and Al-based solders, Ti-based solders are based on Ti2The AlNb-based alloy has good wettability on the surface, and the joint has high strength after welding and excellent corrosion resistance. However, the conventional Ti-based brazing filler metal has the following three disadvantages: first, Ti2The AlNb-based alloy is used as a titanium alloy material used at high temperature, the use temperature of the AlNb-based alloy is higher than that of a common titanium alloy, and the high-temperature performance of a welding joint is reduced when the low-temperature Ti-based brazing filler metal is adopted for welding (such as Ti-Zr-Cu-Ni brazing filler metal and the like); second, Ti2The common solid solution temperature of AlNb-based alloy is 980 ℃/2-4 h, if high-temperature Ti-based brazing filler metal is adopted for welding (such as Ti-Ni-Nb-based brazing filler metal, Ti-Cr-Ta/Nb-based brazing filler metal and the like), the base material structure can be subjected to phase change, the mechanical property of the base material can be changed, and the Ti can not be achieved2Service requirements of the AlNb-based alloy parent metal; further, Ti2AlNb-based alloys also represent a class of titanium alloys with similar phase transition characteristics, and the brazing filler metal capable of meeting the brazing requirements of the titanium alloys is currently under fresh research.
Disclosure of Invention
In view of the above, in order to solve at least one technical problem in the three aspects, the invention aims to provide a Ti-based alloy suitable for Ti2The medium-temperature Ti-based brazing filler metal for brazing the same or different AlNb-based alloy materials and the preparation method and the brazing process thereof can not only meet the requirement of Ti2The brazing requirement of the same material and different material of the AlNb-based alloy is expanded, the application space of the AlNb-based alloy in aviation and aerospace is expanded, and other titanium alloys with similar phase change characteristics can be realizedThe requirement of braze joint.
In order to achieve the above purpose, the technical scheme of the invention is as follows:
ti2The medium-temperature Ti-based brazing filler metal for brazing the same or different AlNb-based alloy comprises the following components in percentage by weight: 15 to 40 percent of Ni (preferably 25 to 35 percent), 1 to 15 percent of Co or 1 to 15 percent of Mo, less than or equal to 5 percent of one or more than two of trace elements of Al, B, Fe, Cu, Cr, Mn, Mg, Ag, Nb and Zn, less than or equal to 2 percent of one or more than two of trace elements of Zr, Hf, V, Ta, W, Au, Si, Sn, Pd and Ga, and the balance of Ti element and inevitable impurity elements.
The Ti2The medium-temperature Ti-based brazing filler metal for the same-material or different-material brazing of the AlNb-based alloy comprises a small amount of elements and trace elements such as Al, B, Fe, Cu, Cr, Mn, Mg, Ag, Nb, Zn, Zr, Hf, V, Ta, W, Au, Si, Sn, Pd and Ga, and the combination mode adopts one of the following modes:
(1) adding one element, Al, B, Fe, Cu, Cr, Mn, Mg, Ag, Nb, Zn, Zr, Hf, V, Ta, W, Au, Si, Sn, Pd and Ga;
(2) adding two elements, Al + B, Al + Nb, Al + Cu, Nb + Cr or Cu + B;
(3) adding three elements, Al + B + Nb, Al + B + Cr, Nb + Cr + B, Al + B + Ag or Mg + B + Ag;
(4) adding four elements, Al + B + Nb + Cr, Al + B + Nb + Cu or Al + B + Mg + Zn;
(5) adding five elements, Al + B + Nb + Cr + Cu or Al + B + Mg + Nb + Zn;
(6) adding six elements, Al + B + Nb + Cr + Mg + Ag or Al + B + Cu + Cr + Mg + Ag;
(7) adding seven elements, Al + B + Nb + Cr + Cu + Ag + Zn;
(8) adding eight elements, Al + B + Nb + Cr + Cu + Mg + Ag + Zn;
(9) adding nine elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn;
(10) adding ten elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe;
(11) eleven elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr are added;
(12) adding twelve elements, Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf;
(13) adding thirteen elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V;
(14) adding fourteen elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta;
(15) adding fifteen elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W;
(16) adding sixteen elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au;
(17) adding seventeen elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si;
(18) adding eighteen elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn;
(19) adding nineteen elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn + Pd;
(20) adding twenty elements, Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn + Pd + Ga.
The Ti2The preparation method of the medium-temperature Ti-based brazing filler metal for brazing the same or different AlNb-based alloy comprises the following steps:
(1) weighing raw materials on an electronic balance according to a proportion, wherein the purity of the raw materials is over 99.9wt%, and because Mn element can volatilize in a large amount during smelting, Mn element needs to be compensated when the components are prepared, and the compensation rate of the Mn element is 1-2 wt%;
(2) placing the raw materials prepared according to the proportion in a high-vacuum non-consumable electric arc furnace protected by Ar atmosphere;
(3) before smelting, the furnace is firstly vacuumized to 1 x 10-3~1×10-4Pa, filling argon to wash the furnace for 2-4 times, and vacuumizing to 1 × 10-3~1×10-4Pa, argon is filled again to be more than 0.035 MPa;
(4) smelting, namely repeatedly smelting the sample in the water-cooled copper crucible for 8-10 times under the action of electromagnetic stirring in order to make the as-cast alloy uniform, and overturning the sample by using an inverted poking rod;
(5) the alloy after smelting is prepared Ti2AlNb-based alloy medium-temperature Ti-based brazing filler metal master alloyGold;
(6) carrying out annealing treatment on the brazing filler metal master alloy in a vacuum heat treatment furnace at 700-900 ℃ for 10-15 h to make the components of the brazing filler metal master alloy more uniform;
(7) crushing the brazing filler metal master alloy, and then loading the crushed brazing filler metal master alloy into a quartz glass tube of a single-roller melt-spun machine; the cross section of the quartz glass tube nozzle is rectangular, the length a of the quartz glass tube nozzle is 6-8 mm, and the width b of the quartz glass tube nozzle is 0.5-1 mm;
(8) clamping a quartz glass tube in an induction heating ring of a single-roller melt-spun machine, and adjusting the distance between a nozzle of the quartz glass tube and the surface of a copper roller to be 0.2-0.3 mm so as to ensure that liquid sprayed on the copper roller is in a flat flow state and form a stable flow state;
(9) closing the furnace door of the single-roller melt-spun machine, and vacuumizing to 1.5 multiplied by 10 by adopting a mechanical pump-1Pa above, molecular pump pumping high vacuum to 3 × 10-3The pressure is above Pa, and then the cavity of the single-roller melt-spun machine is filled with high-purity Ar gas;
(10) starting a high-frequency power supply of the single-roller melt-spun machine, carrying out high-frequency induction heating on the master alloy in the quartz glass tube until the master alloy is completely and uniformly melted, and keeping the melt-blown temperature T at 1100-1250 ℃ for 30 seconds to 2 minutes;
(11) starting a motor of the single-roller melt-spun machine, selecting a copper roller with the diameter of 220-240 mm and the width of 30-50 mm, and adjusting the rotating speed u of the copper rollers=20~35m/s;
(12) Regulating Ar gas pressure to 0.1-0.3 MPa, continuously spraying overheated melt in a quartz glass tube onto the surface of a cooling copper roller rotating at high speed by using high-pressure argon gas, and quenching liquid metal to form a foil strip shape, thereby obtaining Ti2The AlNb-based alloy is brazed with medium-temperature Ti-based brazing filler metal in the same material or different materials.
The Ti2The preparation method of the medium-temperature Ti-based brazing filler metal for the same-material or different-material brazing of the AlNb-based alloy comprises the step (1), when Mn element is added into the brazing filler metal, because the Mn element can be volatilized in a large amount during smelting, element compensation needs to be carried out on the Mn element during composition preparation, and the compensation rate of the Mn element is 1-2 wt%.
The Ti2The preparation method of the medium-temperature Ti-based brazing filler metal for the same-material or different-material brazing of the AlNb-based alloy is preferably that in the step (3),and argon is filled again to 0.04-0.08 MPa.
The Ti2The preparation method of the medium-temperature Ti-based brazing filler metal for the same-material or different-material brazing of the AlNb-based alloy is preferred, and in the step (9), the medium-temperature Ti-based brazing filler metal is pumped by a mechanical pump to be vacuum-pumped to 1 x 10-1~1×10-2Pa, molecular pump pumping high vacuum to 1X 10-3~1× 10-4Pa, filling argon to 0.04-0.08 MPa.
The Ti2The brazing process of middle temperature Ti-base brazing filler metal for brazing same or different AlNb-base alloy material includes brazing Ti in the first step2The method comprises the following steps of sequentially carrying out ultrasonic cleaning on an AlNb-based alloy same-material or different-material brazing medium-temperature Ti-based brazing filler metal and an alloy sample to be welded in an acetone solution and an ethanol solution for 10-20 min respectively to remove surface impurities, taking out and drying, assembling in a brazing clamp according to the sequence of the alloy to be welded/the brazing filler metal/the alloy to be welded, and placing in a vacuum furnace for brazing: firstly, heating a sample to 800-900 ℃ at a heating rate of 5-15 ℃/min, preserving heat for 5-15 min, heating to 980-1040 ℃ at a heating rate of 10-20 ℃/min, preserving heat for 0-120 min, and ensuring that the vacuum degree in the brazing process is not less than 5 multiplied by 10-3Pa; and after the brazing is finished, cooling to room temperature along with the furnace.
The Ti2The brazing process of the medium-temperature Ti-based brazing filler metal for brazing the same material or different materials of the AlNb-based alloy is preferred, and the vacuum degree in the brazing process is 5 multiplied by 10-3~1×10-4Pa。
The design idea of the invention is as follows: based on a ternary phase diagram, combines the action rule of alloy elements in the titanium alloy and Ti2The phase change characteristic and the innovative research and development of the AlNb-based alloy are suitable for Ti2The AlNb-based alloy and the titanium alloy solder with the same phase change characteristics fill the blank of the alloy solder, enrich the types of the titanium alloy solder and obviously improve the high-temperature performance of a soldered joint.
The invention has the following advantages and beneficial effects:
1. the invention relates to a multi-element medium-temperature Ti-based brazing filler metal, which is in Ti2The surface of the AlNb-based alloy has good wettability and good fluidity during brazing, can fully exert the capillary adsorption function, and the brazing filler metal can fully fill brazing seam gaps, thereby obtaining compactThe high strength joint of (1).
2. The multi-element medium-temperature Ti-based brazing filler metal is a thin strip-shaped brazing filler metal, the thickness of the brazing filler metal is about 45 mu m, the brazing gap can be further reduced, the melting point of the multi-element medium-temperature Ti-based brazing filler metal is obviously higher than that of Ag-based brazing filler metal, Al-based brazing filler metal and other Ti-based brazing filler metals, and the use temperature of the brazed material is obviously increased on the premise of not influencing the performance of a base metal, so that the high-temperature tensile strength of the multi-element medium-temperature Ti-based brazing filler metal is obviously better than that of the Ag-based brazing filler metal, the Al-based brazing filler metal and other Ti-based brazing filler metals.
3. The multi-element medium-temperature Ti-based brazing filler metal disclosed by the invention contains a very small amount of noble metals, so that the price is low and the cost is saved.
4. The multi-element medium-temperature Ti-based brazing filler metal does not contain toxic elements such as Be and the like, and the preparation and use processes are safe.
Detailed Description
The following examples are only a part of the examples of the present invention, and not all of them. All other embodiments obtained by persons skilled in the art based on the embodiments of the present invention without any creative work belong to the protection scope of the present invention.
In the specific implementation, Ti is adopted2Medium temperature Ti-base brazing filler metal for brazing same or different AlNb-base alloy to Ti2And carrying out vacuum brazing on the same material or different materials of the AlNb-based alloy. Wherein, Ti2The AlNb-based alloy comprises the following components in atomic percentage: ti-22Al-24Nb-0.5 Mo. The other special material alloy clad brazing parent metal refers to: (1) with Ti2AlNb alloys have similar phase transformation requirements, such as: ti60 alloy, etc.; (2) other brands of intermetallic compounds, such as: ti4822 alloy and 45XD alloy, etc.
Example 1
In this example, Ti2Brazing the same material of AlNb-based alloy, based on the weight percentage, Ti2The AlNb-based alloy medium-temperature Ti-based brazing filler metal comprises the following components: 28-33% of Ni, 2-7% of Co or 3-7% of Mo, and one or more than two of Al, B, Fe, Cu, Cr, Mn, Mg, Ag, Nb and Zn is less than or equal to 5%. Wherein the addition amount of each element is Al: 0 to 5%, B: 0-3%, Fe: 0-5%, Cu: 0-5%, Mn:0-5%, Cr: 0-5%, Mg: 0-5%, Ag: 0-4%, Nb: 0-5% and Zn: 0 to 4 percent; the balance of Ti and inevitable impurity elements. Among the impurity elements of the brazing filler metal, N<0.02wt.%,H<0.02wt.%,O<0.2 wt.%; the trace elements are common elements in titanium alloy, such as: one or more than two of Zr, Hf, V, Ta, W, Au, Si, Sn, Pd, Ga and the like, the total content is 1 percent; the combination of minor elements and trace elements is as follows:
(1) adding one element, Al, B, Fe, Cu, Cr, Mn, Mg, Ag, Nb, Zn, Zr, Hf, V, Ta, W, Au, Si, Sn, Pd and Ga independently, wherein the addition amount is 3 percent;
(2) adding two elements, such as Al + B, Al + Nb, Al + Cu, Nb + Cr or Cu + B, and the like, wherein the addition amount is 3%;
(3) adding three elements, such as Al + B + Nb, Al + B + Cr, Nb + Cr + B, Al + B + Ag or Mg + B + Ag, with the addition amount of 3%;
(4) adding four elements, such as Al + B + Nb + Cr, Al + B + Nb + Cu or Al + B + Mg + Zn, with the addition amount of 3%;
(5) adding five elements, such as Al + B + Nb + Cr + Cu or Al + B + Mg + Nb + Zn, with the addition amount of 3%;
(6) adding six elements, such as Al + B + Nb + Cr + Mg + Ag or Al + B + Cu + Cr + Mg + Ag, with the addition amount of 3%;
(7) seven elements, such as Al + B + Nb + Cr + Cu + Ag + Zn and the like are added, and the addition amount is 3 percent;
(8) adding eight elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn, with the addition amount of 3%;
(9) nine elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn, are added, and the addition amount is 3 percent;
(10) ten elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe, are added, and the addition amount is 3 percent;
(11) eleven elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr, are added, and the addition amount is 3%;
(12) twelve elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf, are added, and the addition amount is 3%;
(13) adding thirteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V, with the addition amount of 3%;
(14) adding fourteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta, with the addition amount of 3%;
(15) fifteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W and the like are added, and the addition amount is 3%;
(16) adding sixteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au and the like, wherein the addition amount is 3%;
(17) seventeen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si, are added, and the addition amount is 3%;
(18) eighteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn, are added, and the addition amount is 3%;
(19) nineteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn + Pd, are added, and the addition amount is 3%;
(20) adding twenty elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn + Pd + Ga, wherein the addition amount is 3%.
In this example, Ti2The AlNb-based alloy medium-temperature Ti-based brazing filler metal is prepared by the following steps and processes:
(1) weighing raw materials on an electronic balance according to a proportion, wherein the purity of the raw materials is over 99.9 wt%; because Mn element can volatilize in a large amount during smelting, the Mn element needs to be compensated during composition preparation, and the compensation rate of the Mn element is 1-2 wt% after a plurality of tests;
(2) placing the raw materials prepared according to the proportion in a high-vacuum non-consumable electric arc furnace protected by Ar atmosphere;
(3) before smelting, the furnace is firstly vacuumized to 4 multiplied by 10-4Pa, filling argon to wash the furnace for 2-4 times, and vacuumizing to 4 multiplied by 10- 4Pa, argon is filled again to 0.04 MPa;
(4) smelting, namely repeatedly smelting the sample in the water-cooled copper crucible for 8-10 times under the action of electromagnetic stirring in order to make the as-cast alloy uniform, and overturning the sample by using an inverted poking rod; wherein, the meaning of turning over the sample by the reverse poking stick is as follows: turning the button ingot which is smelted each time up and down so as to smelt the alloy evenly;
(5) fusion furnaceThe refined alloy is prepared Ti2Mother alloy of AlNb-based alloy medium temperature Ti-based brazing filler metal;
(6) the brazing filler metal master alloy is annealed at the temperature of 800 ℃/12h in a vacuum heat treatment furnace, so that the components of the brazing filler metal master alloy are more uniform;
(7) and crushing the brazing filler metal master alloy, and then filling the crushed brazing filler metal master alloy into a quartz glass tube of a single-roller melt-spun machine. The cross section of the quartz glass tube nozzle is rectangular, the length a of the quartz glass tube nozzle is 6-8 mm, and the width b of the quartz glass tube nozzle is 0.5-1 mm;
(8) clamping a quartz glass tube in an induction heating ring of a single-roller melt-spun machine, and adjusting the distance between a nozzle of the quartz glass tube and the surface of a copper roller to be 0.2-0.3 mm so as to ensure that liquid sprayed on the copper roller is in a flat flow state and form a stable flow state;
(9) closing the furnace door of the single-roller melt-spun machine, and vacuumizing to 1 × 10 by using a mechanical pump-1Pa, molecular pump pumping high vacuum to 2X 10-3Pa, then filling high-purity Ar gas (the volume purity is 99.99%) into a cavity of the single-roller belt throwing machine;
(10) starting a high-frequency power supply, carrying out high-frequency induction heating on the master alloy in the quartz glass tube until the master alloy is completely and uniformly melted, keeping the melt-blowing temperature T at 1200 ℃, and keeping the temperature of the overheated melt for 1 minute;
(11) starting a motor, selecting a copper roller with the diameter of 230mm and the width of 40mm, and adjusting the rotating speed u of the copper rollers=30m/s;
(12) Regulating Ar gas pressure to 0.2MPa, continuously spraying the overheated melt in the quartz glass tube onto the surface of a cooling copper roller rotating at high speed by using high-pressure argon gas, and quenching the liquid metal to form a foil strip shape, thereby obtaining the Ti-containing alloy Ti2An AlNb-based alloy medium-temperature Ti-based brazing filler metal. The thickness of the quenching brazing filler metal foil prepared by the process is 0.045 +/-0.003 mm, the surface is smooth, and the two sides are smooth.
In this example, Ti2The brazing process of the AlNb-based alloy medium-temperature Ti-based brazing filler metal comprises the following steps: before brazing, Ti2AlNb-based alloy medium-temperature Ti-based brazing filler metal and Ti2Sequentially carrying out ultrasonic cleaning on to-be-welded samples of AlNb-based alloy in acetone solution and ethanol solution for 15min respectively to remove surface impurities, taking out and drying, and carrying out Ti treatment2AlNb-based alloy/brazing filler metal/Ti2Assembling the AlNb-based alloy in a brazing clamp in sequence, and brazing in a vacuum furnace: firstly, heating a sample to 900 ℃ at a heating rate of 10 ℃/min, preserving heat for 10min, heating to 1040 ℃ at a heating rate of 15 ℃/min, preserving heat for 1h, wherein the vacuum degree in the brazing process is 4 multiplied by 10-3Pa. And after the brazing is finished, cooling to room temperature along with the furnace.
Vacuum brazing of Ti by using the medium-temperature Ti-based brazing filler metal2The high-temperature performance of the AlNb-based alloy is far higher than that of Ag-based brazing filler metal, Al-based brazing filler metal and other Ti-based brazing filler metals, and the tensile strength of a welding joint reaches 120-131 MPa at 950 ℃.
For example:
the components of Ni 28%, Co 7%, Fe 3% and Ti in balance, and the tensile strength of the welding joint reaches 131MPa at 950 ℃.
The tensile strength of the welding joint reaches 124MPa at 950 ℃ when the components are Ni 33%, Co 2%, B3% and the balance Ti.
The components of Ni 28%, Mo 6%, Mn 3% and the balance Ti, and the tensile strength of the welded joint reaches 127MPa at 950 ℃.
The tensile strength of the welded joint reaches 130MPa at 950 ℃ when the components are Ni 33%, Mo 3%, Fe 1%, B1% and Mn 1%.
The tensile strength of the welded joint reaches 120MPa at 950 ℃ when the components are Ni 30%, Mo 5%, B1% and Mn 2%.
Example 2
In this example, Ti2Dissimilar brazing of AlNb-based alloy and gamma-TiAl-based alloy, wherein the dissimilar brazing comprises Ti2The AlNb-based alloy medium-temperature Ti-based brazing filler metal comprises the following components: 30-35% of Ni, 5-7% of Co or 1-8% of Mo, and one or more of Al, B, Fe, Cu, Cr, Mn, Mg, Ag, Nb and Zn is less than or equal to 5%. Wherein the addition amount of each element is Al: 0-5%, B: 0-3%, Fe: 0-5%, Cu: 0-5%, Mn: 0-5%, Cr: 0-5%, Mg: 0-5%, Ag: 0-4%, Nb: 0-5% and Zn: 0 to 4 percent; the balance of Ti and inevitable impurity elements. Among the impurity elements of the brazing filler metal, N<0.02wt.%,H<0.02wt.%,O<0.2 wt.%; the trace element is titanium alloySuch as: one or more of Zr, Hf, V, Ta, W, Au, Si, Sn, Pd, Ga and the like, the total content being 0.5%; the combination of minor elements and trace elements is listed below:
(1) adding one element, Al, B, Fe, Cu, Cr, Mn, Mg, Ag, Nb, Zn, Zr, Hf, V, Ta, W, Au, Si, Sn, Pd and Ga independently, wherein the addition amount is 2 percent;
(2) adding two elements, such as Al + B, Al + Nb, Al + Cu, Nb + Cr or Cu + B and the like, wherein the addition amount is 2%;
(3) adding three elements, such as Al + B + Nb, Al + B + Cr, Nb + Cr + B, Al + B + Ag or Mg + B + Ag, with the addition amount of 2%;
(4) adding four elements, such as Al + B + Nb + Cr, Al + B + Nb + Cu or Al + B + Mg + Zn, with the addition amount of 2%;
(5) five elements are added, such as Al + B + Nb + Cr + Cu or Al + B + Mg + Nb + Zn, and the addition amount is 2 percent;
(6) adding six elements, such as Al + B + Nb + Cr + Mg + Ag or Al + B + Cu + Cr + Mg + Ag, with the addition amount of 2%;
(7) seven elements, such as Al + B + Nb + Cr + Cu + Ag + Zn and the like are added, and the addition amount is 2 percent;
(8) adding eight elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn, with the addition amount of 2%;
(9) nine elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn and the like are added, and the addition amount is 2 percent;
(10) ten elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe, are added, and the addition amount is 2 percent;
(11) eleven elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr, are added, and the addition amount is 2%;
(12) twelve elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf, are added, and the addition amount is 2%;
(13) adding thirteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V, with the addition amount of 2%;
(14) adding fourteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta, with the addition amount of 2%;
(15) fifteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W and the like are added, and the addition amount is 2%;
(16) adding sixteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au and the like, wherein the addition amount is 2%;
(17) seventeen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si, are added, and the addition amount is 2 percent;
(18) eighteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn, are added, and the addition amount is 2%;
(19) nineteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn + Pd, are added, and the addition amount is 2%;
(20) adding twenty elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn + Pd + Ga, wherein the addition amount is 2%.
In this example, Ti2The AlNb-based alloy medium-temperature Ti-based brazing filler metal is prepared by the following steps and processes:
(1) weighing raw materials on an electronic balance according to a proportion, wherein the purity of the raw materials is over 99.9 wt%; because Mn element can volatilize in a large amount during smelting, the Mn element needs to be compensated during composition preparation, and the compensation rate of the Mn element is 1-2 wt% after a plurality of tests;
(2) placing the raw materials prepared according to the proportion in a high-vacuum non-consumable electric arc furnace protected by Ar atmosphere;
(3) before smelting, the furnace is firstly vacuumized to 2 x 10-4Pa, filling argon to wash the furnace for 2-4 times, and vacuumizing to 2 multiplied by 10- 4Pa, argon is filled again to 0.05 MPa;
(4) smelting, namely repeatedly smelting the sample in the water-cooled copper crucible for 8-10 times under the action of electromagnetic stirring in order to make the as-cast alloy uniform, and overturning the sample by using an inverted poking rod;
(5) the alloy after smelting is prepared Ti2Mother alloy of AlNb-based alloy medium temperature Ti-based brazing filler metal;
(6) the brazing filler metal master alloy is annealed at 750 ℃/15h in a vacuum heat treatment furnace, so that the components of the brazing filler metal master alloy are more uniform;
(7) and crushing the brazing filler metal master alloy, and then filling the crushed brazing filler metal master alloy into a quartz glass tube of a single-roller melt-spun machine. The cross section of the quartz glass tube nozzle is rectangular, the length a of the quartz glass tube nozzle is 6-8 mm, and the width b of the quartz glass tube nozzle is 0.5-1 mm;
(8) clamping a quartz glass tube in an induction heating ring of a single-roller melt-spun machine, and adjusting the distance between a nozzle of the quartz glass tube and the surface of a copper roller to be 0.2-0.3 mm so as to ensure that liquid sprayed on the copper roller is in a flat flow state and form a stable flow state;
(9) closing the furnace door of the single-roller melt-spun machine, and vacuumizing to 1.5 multiplied by 10 by adopting a mechanical pump-1Pa, molecular pump pumping high vacuum to 3X 10-3Pa, then filling high-purity Ar gas (the volume purity is 99.99%) into a cavity of the single-roller belt throwing machine;
(10) starting a high-frequency power supply, carrying out high-frequency induction heating on the master alloy in the quartz glass tube until the master alloy is completely and uniformly melted, keeping the melt-blowing temperature T of 1150 ℃, and keeping the temperature of the overheated melt for 1 minute;
(11) starting a motor, selecting a copper roller with the diameter of 230mm and the width of 40mm, and adjusting the rotating speed u of the copper rollers=25m/s;
(12) The Ar gas pressure is adjusted to 0.15MPa, the superheated melt in the quartz glass tube is continuously sprayed onto the surface of a cooling copper roller rotating at high speed by using high-pressure argon, and the liquid metal is rapidly cooled to form a foil strip shape, so that the medium-temperature Ti-based brazing filler metal of the Ti2 AlNb-based alloy is obtained. The thickness of the quenching brazing filler metal foil prepared by the process is 0.045 +/-0.002 mm, the surface is smooth, and the two sides are smooth.
In this example, Ti2The brazing process of the AlNb-based alloy medium-temperature Ti-based brazing filler metal comprises the following steps: before brazing, Ti2AlNb-based alloy medium-temperature Ti-based brazing filler metal and Ti2Sequentially carrying out ultrasonic cleaning on samples to be welded of AlNb-based alloy and gamma-TiAl-based alloy in acetone solution and ethanol solution for 10min respectively to remove surface impurities, taking out and drying the samples, and carrying out ultrasonic cleaning according to Ti2Assembling AlNb-based alloy/brazing filler metal/gamma-TiAl-based alloy in a brazing clamp in sequence, and brazing in a vacuum furnace: firstly, heating a sample to 850 ℃ at a heating rate of 8 ℃/min, preserving heat for 8min, heating to 1025 ℃ at a heating rate of 10 ℃/min, preserving heat for 30min, and ensuring the vacuum degree in the brazing process to be 5 multiplied by 10-3Pa. And after the brazing is finished, cooling to room temperature along with the furnace.
Adopts the medium-temperature Ti-based brazing filler metalVacuum brazing of Ti2The high-temperature performance of the AlNb-based alloy and the gamma-TiAl-based alloy is far higher than that of Ag-based solder, Al-based solder and other Ti-based solder, and the tensile strength of a welding joint reaches 115 MPa-127 MPa at 950 ℃.
For example:
the components of Ni 35%, Co 5%, Nb 2% and the balance of Ti, and the tensile strength of the welded joint reaches 127MPa at 950 ℃.
The tensile strength of the welded joint reaches 117MPa at 950 ℃ when the components are Ni 30%, Co 7%, Zr 2% and the balance Ti.
The components of Ni 35%, Mo 1%, Cu 2% and the balance Ti, and the tensile strength of the welded joint reaches 120MPa at 950 ℃.
The components of Ni 30%, Mo 8%, Nb 1%, Cu 1% and the balance Ti, and the tensile strength of the welded joint reaches 119MPa at 950 ℃.
The components of Ni 33%, Co 6%, Nb 0.5%, Cu 0.5%, Zr 1% and the balance Ti, and the tensile strength of the welded joint reaches 124MPa at 950 ℃.
Example 3
In this example, Ti2AlNb-based alloy and alpha2-Ti3Dissimilar brazing of Al-based alloy, by weight percent, Ti2The AlNb-based alloy medium-temperature Ti-based brazing filler metal comprises the following components: ni 25-30%, Co 1-4% or Mo 2-5%, one or more of Al, B, Fe, Cu, Cr, Mn, Mg, Ag, Nb and Zn less than or equal to 5%. Wherein the addition amount of each element is Al: 0-5%, B: 0-3%, Fe: 0-5%, Cu: 0-5%, Mn: 0-5%, Cr: 0 to 5%, Mg: 0-5%, Ag: 0-4%, Nb: 0-5% and Zn: 0 to 4 percent; the balance of Ti and inevitable impurity elements. Among the impurity elements of the brazing filler metal, N<0.02wt.%,H<0.02wt.%,O<0.2 wt.%; the trace elements are common elements in titanium alloy, such as: one or more than two of Zr, Hf, V, Ta, W, Au, Si, Sn, Pd, Ga and the like, the total content is 2 percent; the combination of minor elements and trace elements is as follows:
(1) adding one element, Al, B, Fe, Cu, Cr, Mn, Mg, Ag, Nb, Zn, Zr, Hf, V, Ta, W, Au, Si, Sn, Pd and Ga independently, wherein the addition amount is 4%;
(2) adding two elements, such as Al + B, Al + Nb, Al + Cu, Nb + Cr or Cu + B and the like, wherein the addition amount is 4%;
(3) adding three elements, such as Al + B + Nb, Al + B + Cr, Nb + Cr + B, Al + B + Ag or Mg + B + Ag, with the addition amount of 4%;
(4) adding four elements, such as Al + B + Nb + Cr, Al + B + Nb + Cu or Al + B + Mg + Zn, with the addition amount of 4%;
(5) five elements are added, such as Al + B + Nb + Cr + Cu or Al + B + Mg + Nb + Zn, and the addition amount is 4%;
(6) adding six elements, such as Al + B + Nb + Cr + Mg + Ag or Al + B + Cu + Cr + Mg + Ag, with the addition amount of 4%;
(7) seven elements, such as Al + B + Nb + Cr + Cu + Ag + Zn and the like are added, and the addition amount is 4 percent;
(8) adding eight elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn, with the addition amount of 4%;
(9) nine elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn and the like are added, and the addition amount is 4%;
(10) ten elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe, are added, and the addition amount is 4 percent;
(11) eleven elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr, are added, and the addition amount is 4%;
(12) twelve elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf, are added, and the addition amount is 4%;
(13) adding thirteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V, with the addition amount of 4%;
(14) adding fourteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta, with the addition amount of 4%;
(15) fifteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W and the like are added, and the addition amount is 4%;
(16) adding sixteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au and the like, wherein the addition amount is 4%;
(17) seventeen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si, are added, and the addition amount is 4%;
(18) eighteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn, are added, and the addition amount is 4%;
(19) nineteen elements, such as Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn + Pd, are added, and the addition amount is 4%;
(20) adding twenty elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn + Pd + Ga, wherein the addition amount is 4%.
In this example, Ti2The AlNb-based alloy medium-temperature Ti-based brazing filler metal is prepared by the following steps and processes:
(1) weighing raw materials on an electronic balance according to a proportion, wherein the purity of the raw materials is over 99.9 wt%; because Mn element can volatilize in a large amount during smelting, the Mn element needs to be compensated during composition preparation, and the compensation rate of the Mn element is 1-2 wt% after a plurality of tests;
(2) placing the raw materials prepared according to the proportion in a high-vacuum non-consumable electric arc furnace protected by Ar atmosphere;
(3) before smelting, the furnace is firstly vacuumized to 6 x 10-4Pa, filling argon to wash the furnace for 2-4 times, and vacuumizing to 6 multiplied by 10- 4Pa, argon is filled again to 0.06 MPa;
(4) smelting, namely repeatedly smelting the sample in the water-cooled copper crucible for 8-10 times under the action of electromagnetic stirring in order to make the as-cast alloy uniform, and overturning the sample by using an inverted poking rod;
(5) the alloy after smelting is prepared Ti2Mother alloy of AlNb-based alloy medium temperature Ti-based brazing filler metal;
(6) the brazing filler metal master alloy is annealed at 850 ℃/10h in a vacuum heat treatment furnace, so that the components of the brazing filler metal master alloy are more uniform;
(7) and crushing the brazing filler metal master alloy, and then filling the crushed brazing filler metal master alloy into a quartz glass tube of a single-roller melt-spun machine. The cross section of the quartz glass tube nozzle is rectangular, the length a of the quartz glass tube nozzle is 6-8 mm, and the width b of the quartz glass tube nozzle is 0.5-1 mm;
(8) clamping a quartz glass tube in an induction heating ring of a single-roller melt-spun machine, and adjusting the distance between a nozzle of the quartz glass tube and the surface of a copper roller to be 0.2-0.3 mm so as to ensure that liquid sprayed on the copper roller is in a flat flow state and form a stable flow state;
(9) closing the furnace door of the single-roller melt-spun machine, and vacuumizing to 0.5 multiplied by 10 by adopting a mechanical pump-1Pa, molecular pump pumping high vacuum to 1.5X 10-3Pa, then filling high-purity Ar gas (the volume purity is 99.99%) into a cavity of the single-roller belt throwing machine;
(10) starting a high-frequency power supply, carrying out high-frequency induction heating on the master alloy in the quartz glass tube until the master alloy is completely and uniformly melted, keeping the melt-blowing temperature T of 1250 ℃, and keeping the temperature of the overheated melt for 1 minute;
(11) starting a motor, selecting a copper roller with the diameter of 230mm and the width of 40mm, and adjusting the rotating speed u of the copper rollers=35m/s;
(12) The Ar gas pressure is adjusted to 0.25MPa, the superheated melt in the quartz glass tube is continuously sprayed onto the surface of a cooling copper roller rotating at high speed by using high-pressure argon, and the liquid metal is rapidly cooled to form a foil strip shape, so that the medium-temperature Ti-based brazing filler metal of the Ti2 AlNb-based alloy is obtained. The thickness of the quenching brazing filler metal foil prepared by the process is 0.045 +/-0.003 mm, the surface is smooth, and the two sides are smooth.
In this example, Ti2The brazing process of the AlNb-based alloy medium-temperature Ti-based brazing filler metal comprises the following steps: before brazing, Ti2AlNb-based alloy medium-temperature Ti-based brazing filler metal and Ti2AlNb-based alloy, alpha2-Ti3Sequentially carrying out ultrasonic cleaning on to-be-welded Al-based alloy samples in acetone solution and ethanol solution for 20min respectively to remove surface impurities, taking out and drying the to-be-welded Al-based alloy samples, and carrying out ultrasonic cleaning according to Ti2AlNb-based alloy/brazing filler metal/alpha2-Ti3Assembling Al-based alloys in a brazing clamp in sequence, and brazing in a vacuum furnace: firstly, heating a sample to 800 ℃ at a heating rate of 12 ℃/min, preserving heat for 12min, then heating to 990 ℃ at a heating rate of 20 ℃/min, preserving heat for 90min, and ensuring that the vacuum degree in the brazing process is 3 multiplied by 10-3Pa. And after the brazing is finished, cooling to room temperature along with the furnace.
Vacuum brazing of Ti by using the medium-temperature Ti-based brazing filler metal2AlNb-based alloy and alpha2-Ti3The high-temperature performance of the Al-based alloy is far higher than that of Ag-based solder, Al-based solder and other Ti-based solder, and the tensile strength of a welding joint reaches 103-116 MPa at 950 ℃.
For example:
the components of Ni 25%, Co 4%, Fe 4% and Ti in balance, and the tensile strength of the welding joint reaches 115MPa at 950 ℃.
The components of Ni 30%, Co 1%, B4% and the balance of Ti, and the tensile strength of the welding joint reaches 109MPa at 950 ℃.
The components of Ni 25%, Mo 5%, Zr 4% and the balance Ti, and the tensile strength of the welded joint reaches 111MPa at 950 ℃.
The components of Ni 30%, Mo 2%, Fe 2%, Zr 2% and the balance of Ti, and the tensile strength of the welding joint reaches 105MPa at 950 ℃.
The components of Ni 28%, Co 3%, Fe 1%, Zr 1%, Cr 2% and Ti in balance, and the tensile strength of the welded joint reaches 107MPa at 950 ℃.
The example results show that compared with the existing solder, the solder prepared by the invention has the advantages of proper melting point, excellent wettability and high-temperature mechanical property, and simple preparation and soldering processes. Vacuum brazing of Ti by adopting the warm Ti-based brazing filler metal of the invention2On the premise of not losing the performance of the base metal, the high-temperature performance of the AlNb-based alloy is far higher than that of Ag-based brazing filler metal, Al-based brazing filler metal and other Ti-based brazing filler metals, and the high-temperature tensile strength of a welding joint is superior to that of the base metal alloy. Therefore, the blank of the titanium alloy medium-temperature brazing filler metal in the current stage is filled, and the problems that the high-temperature performance of a joint is poor after the existing brazing filler metal is welded, the preparation process and the brazing process of the brazing filler metal are complex and the like are solved.
The above description is only representative of the embodiments of the present invention, and the scope of the present invention is not limited thereto. For researchers in the field, all other embodiments obtained by adding other elements (such as Zr, Hf, Ta, W, V, Si, C, O, and the like), the thickness of the brazing filler metal, the size of the brazing filler metal, the surface roughness of the base metal to be welded and the brazing base metal to the main components of the brazing filler metal are correspondingly adjusted without significantly improving the welding performance belong to the protection scope of the invention. Therefore, other changes and modifications can be made according to the technical scheme and the technical idea of the invention, and the invention still falls into the protection scope covered by the invention.
The above embodiments are only a part of the embodiments of the present invention, and not all embodiments. Many modifications and variations will readily occur to those skilled in the art based upon the description of the embodiments herein, and it is intended that all such additional embodiments be included within the scope of the present invention without the exercise of inventive faculty. The invention has not been described in detail and is in part known to those of skill in the art.

Claims (6)

1. Ti2The medium-temperature Ti-based brazing filler metal for the same-material or different-material brazing of the AlNb-based alloy is characterized by comprising the following components in percentage by weight: 15 to 40 percent of Ni, 1 to 15 percent of Co or 1 to 15 percent of Mo, less than 5 percent of one or more than two of a small amount of elements of Al, B, Fe, Cu, Cr, Mn, Mg, Ag, Nb and Zn, less than 2 percent of one or more than two of trace elements of Zr, Hf, V, Ta, W, Au, Si, Sn, Pd and Ga, and the balance of Ti element and inevitable impurity elements;
small elements and trace elements Al, B, Fe, Cu, Cr, Mn, Mg, Ag, Nb, Zn, Zr, Hf, V, Ta, W, Au, Si, Sn, Pd and Ga, and the combination mode adopts one of the following modes:
(1) adding one element, Al, B, Fe, Cu, Cr, Mn, Mg, Ag, Nb, Zn, Zr, Hf, V, Ta, W, Au, Si, Sn, Pd and Ga;
(2) adding two elements, Al + B, Al + Nb, Al + Cu, Nb + Cr or Cu + B;
(3) adding three elements, Al + B + Nb, Al + B + Cr, Nb + Cr + B, Al + B + Ag or Mg + B + Ag;
(4) adding four elements, Al + B + Nb + Cr, Al + B + Nb + Cu or Al + B + Mg + Zn;
(5) adding five elements, Al + B + Nb + Cr + Cu or Al + B + Mg + Nb + Zn;
(6) adding six elements, Al + B + Nb + Cr + Mg + Ag or Al + B + Cu + Cr + Mg + Ag;
(7) adding seven elements, Al + B + Nb + Cr + Cu + Ag + Zn;
(8) adding eight elements, Al + B + Nb + Cr + Cu + Mg + Ag + Zn;
(9) adding nine elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn;
(10) adding ten elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe;
(11) eleven elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr are added;
(12) adding twelve elements, Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf;
(13) adding thirteen elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V;
(14) adding fourteen elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta;
(15) adding fifteen elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W;
(16) adding sixteen elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au;
(17) adding seventeen elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si;
(18) adding eighteen elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn;
(19) adding nineteen elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn + Pd;
(20) adding twenty elements, namely Al + B + Nb + Cr + Cu + Mg + Ag + Zn + Mn + Fe + Zr + Hf + V + Ta + W + Au + Si + Sn + Pd + Ga;
the Ti2The preparation method of the medium-temperature Ti-based brazing filler metal for brazing the same or different AlNb-based alloy comprises the following steps:
(1) weighing raw materials on an electronic balance according to a proportion, wherein the purity of the raw materials is over 99.9 wt%;
(2) placing the raw materials prepared according to the proportion in a high-vacuum non-consumable electric arc furnace protected by Ar atmosphere;
(3) before smelting, the furnace is firstly vacuumized to 1 x 10-3~1×10-4Pa, filling argon to wash the furnace for 2-4 times, and vacuumizing to 1 × 10-3~1×10-4Pa, argon is filled again to be more than 0.035 MPa;
(4) smelting, namely repeatedly smelting the sample in the water-cooled copper crucible for 8-10 times under the action of electromagnetic stirring in order to make the as-cast alloy uniform, and overturning the sample by using an inverted poking rod;
(5) the alloy after smelting is prepared Ti2Mother alloy of AlNb-based alloy medium temperature Ti-based brazing filler metal;
(6) carrying out annealing treatment on the brazing filler metal master alloy in a vacuum heat treatment furnace at 700-900 ℃ for 10-15 h to make the components of the brazing filler metal master alloy more uniform;
(7) crushing the brazing filler metal master alloy, and then loading the crushed brazing filler metal master alloy into a quartz glass tube of a single-roller melt-spun machine; the cross section of the quartz glass tube nozzle is rectangular, the length a of the quartz glass tube nozzle is 6-8 mm, and the width b of the quartz glass tube nozzle is 0.5-1 mm;
(8) clamping a quartz glass tube in an induction heating ring of a single-roller melt-spun machine, and adjusting the distance between a nozzle of the quartz glass tube and the surface of a copper roller to be 0.2-0.3 mm so as to ensure that liquid sprayed on the copper roller is in a flat flow state and form a stable flow state;
(9) closing the furnace door of the single-roller melt-spun machine, and vacuumizing to 1.5 multiplied by 10 by adopting a mechanical pump-1Pa above, molecular pump pumping high vacuum to 3 × 10-3The pressure is above Pa, and then the cavity of the single-roller melt-spun machine is filled with high-purity Ar gas;
(10) starting a high-frequency power supply of the single-roller melt-spun machine, carrying out high-frequency induction heating on the master alloy in the quartz glass tube until the master alloy is completely and uniformly melted, and keeping the melt-blown temperature T at 1100-1250 ℃ for 30 seconds to 2 minutes;
(11) starting a motor of the single-roller melt-spun machine, selecting a copper roller with the diameter of 220-240 mm and the width of 30-50 mm, and adjusting the rotating speed u of the copper rollers=20~35m/s;
(12) Regulating Ar gas pressure to 0.1-0.3 MPa, continuously spraying overheated melt in a quartz glass tube onto the surface of a cooling copper roller rotating at high speed by using high-pressure argon gas, and quenching liquid metal to form a foil strip shape, thereby obtaining Ti2The AlNb-based alloy is brazed with medium-temperature Ti-based brazing filler metal in the same material or different materials.
2. Ti according to claim 12Medium-temperature Ti-based brazing filler metal for brazing same or different AlNb-based alloysThe method is characterized in that in the step (1), when Mn element is added into the brazing filler metal, the Mn element is volatilized in a large amount during smelting, element compensation needs to be carried out on the Mn element during component preparation, and the compensation rate of the Mn element is 1-2 wt%.
3. Ti according to claim 12The medium-temperature Ti-based brazing filler metal for brazing the same or different AlNb-based alloy is characterized in that in the step (3), argon is filled again to 0.04-0.08 MPa.
4. Ti according to claim 12The medium-temperature Ti-based brazing filler metal for brazing the same or different AlNb-based alloy is characterized in that in the step (9), a mechanical pump is adopted to pump vacuum to 1 multiplied by 10-1~1×10-2Pa, molecular pump pumping high vacuum to 1X 10-3~1×10-4Pa, filling argon to 0.04-0.08 MPa.
5. The Ti of claim 12The brazing process of the medium-temperature Ti-based brazing filler metal for brazing the same or different AlNb-based alloy is characterized in that Ti is brazed before brazing2The method comprises the following steps of sequentially carrying out ultrasonic cleaning on an AlNb-based alloy same-material or different-material brazing medium-temperature Ti-based brazing filler metal and an alloy sample to be welded in an acetone solution and an ethanol solution for 10-20 min respectively to remove surface impurities, taking out and drying, assembling in a brazing clamp according to the sequence of the alloy to be welded/the brazing filler metal/the alloy to be welded, and placing in a vacuum furnace for brazing: firstly, heating a sample to 800-900 ℃ at a heating rate of 5-15 ℃/min, preserving heat for 5-15 min, heating to 980-1040 ℃ at a heating rate of 10-20 ℃/min, preserving heat for 0-120 min, and ensuring that the vacuum degree in the brazing process is not less than 5 multiplied by 10-3Pa; and after the brazing is finished, cooling to room temperature along with the furnace.
6. Ti according to claim 52The brazing process of the medium temperature Ti-based brazing filler metal for brazing the same material or different materials of the AlNb-based alloy is characterized in that the vacuum degree in the brazing process is 5 multiplied by 10-3~1×10-4Pa。
CN202010403203.0A 2020-05-13 2020-05-13 Ti2Medium-temperature Ti-based brazing filler metal for brazing same or different AlNb-based alloys as well as preparation method and brazing process thereof Active CN111702278B (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202010403203.0A CN111702278B (en) 2020-05-13 2020-05-13 Ti2Medium-temperature Ti-based brazing filler metal for brazing same or different AlNb-based alloys as well as preparation method and brazing process thereof

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202010403203.0A CN111702278B (en) 2020-05-13 2020-05-13 Ti2Medium-temperature Ti-based brazing filler metal for brazing same or different AlNb-based alloys as well as preparation method and brazing process thereof

Publications (2)

Publication Number Publication Date
CN111702278A CN111702278A (en) 2020-09-25
CN111702278B true CN111702278B (en) 2021-10-22

Family

ID=72538078

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202010403203.0A Active CN111702278B (en) 2020-05-13 2020-05-13 Ti2Medium-temperature Ti-based brazing filler metal for brazing same or different AlNb-based alloys as well as preparation method and brazing process thereof

Country Status (1)

Country Link
CN (1) CN111702278B (en)

Families Citing this family (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN112846569B (en) * 2020-12-24 2022-08-09 中国航发北京航空材料研究院 Zirconium-based six-element alloy brazing filler metal containing Sn, Hf and Ni and use method
CN112935618B (en) * 2020-12-24 2022-09-20 中国航发北京航空材料研究院 Zr-Ti-Ni-Nb-Hf brazing filler metal for pure titanium and titanium alloy brazing and use method
CN112935623B (en) * 2021-02-05 2023-07-21 天津市金桥焊材集团股份有限公司 Novel Ni-Cr-Co-Mo high-temperature nickel-based welding wire
CN113458655B (en) * 2021-07-01 2022-05-17 安徽工业大学 Hf-containing multi-element boron-free nickel-based alloy brazing filler metal, preparation method and brazing method thereof
CN114310037B (en) * 2022-01-27 2023-06-06 哈尔滨工业大学 NiCrFeCuZrHf brazing filler metal and preparation method thereof
CN114346519B (en) * 2022-03-04 2023-06-20 哈尔滨工业大学 Method for directly brazing TiAl alloy and Ti2AlNb alloy by using high-entropy brazing filler metal foil
CN116551244B (en) * 2023-07-11 2023-10-03 北京航空航天大学 Au-containing low-melting-point nickel-based alloy, brazing filler metal and preparation method and application thereof

Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2005007336A1 (en) * 2003-07-14 2005-01-27 Honeywell International Inc. Low cost brazes for titanium
CN102430874A (en) * 2011-11-01 2012-05-02 北京工业大学 Titanium-based amorphous brazing alloy foil strip for brazing and preparation method for foil strip
CN103567666A (en) * 2013-11-15 2014-02-12 中国航空工业集团公司北京航空制造工程研究所 Strip-shaped brazing filler metal for titanium alloy brazing and Ti2AlNb alloy brazing, preparation method thereof and brazing method
CN103949802A (en) * 2014-04-23 2014-07-30 华南理工大学 Ti-Zr-Cu-Ni-Co-Mo amorphous brazing filler metal and preparing method thereof
CN106925905A (en) * 2017-01-20 2017-07-07 中国科学院金属研究所 A kind of TiAl-base alloy special-purpose high temperature Ti base solders and preparation method thereof and soldering processes
CN106925906A (en) * 2017-01-20 2017-07-07 中国科学院金属研究所 A kind of TiAl-base alloy special-purpose high temperature Ti Zr base solders and preparation method thereof and soldering processes
CN107931763A (en) * 2016-10-12 2018-04-20 天津大学 A kind of method for welding being reliably connected and improve Ti Al Nb alloy self performances
CN108971801A (en) * 2018-08-24 2018-12-11 华南理工大学 A kind of Ti-Zr-Ni-Fe-Cu-Co-Mo-B solder and the preparation method and application thereof
CN110355496A (en) * 2019-05-14 2019-10-22 中国航发北京航空材料研究院 A kind of high temperature resistant solder and soldering processes can be used for gamma-TiAl alloy
CN110666396A (en) * 2019-10-21 2020-01-10 中国航发北京航空材料研究院 Strip-shaped brazing material for titanium alloy medium-low temperature brazing, preparation method and brazing method

Patent Citations (10)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2005007336A1 (en) * 2003-07-14 2005-01-27 Honeywell International Inc. Low cost brazes for titanium
CN102430874A (en) * 2011-11-01 2012-05-02 北京工业大学 Titanium-based amorphous brazing alloy foil strip for brazing and preparation method for foil strip
CN103567666A (en) * 2013-11-15 2014-02-12 中国航空工业集团公司北京航空制造工程研究所 Strip-shaped brazing filler metal for titanium alloy brazing and Ti2AlNb alloy brazing, preparation method thereof and brazing method
CN103949802A (en) * 2014-04-23 2014-07-30 华南理工大学 Ti-Zr-Cu-Ni-Co-Mo amorphous brazing filler metal and preparing method thereof
CN107931763A (en) * 2016-10-12 2018-04-20 天津大学 A kind of method for welding being reliably connected and improve Ti Al Nb alloy self performances
CN106925905A (en) * 2017-01-20 2017-07-07 中国科学院金属研究所 A kind of TiAl-base alloy special-purpose high temperature Ti base solders and preparation method thereof and soldering processes
CN106925906A (en) * 2017-01-20 2017-07-07 中国科学院金属研究所 A kind of TiAl-base alloy special-purpose high temperature Ti Zr base solders and preparation method thereof and soldering processes
CN108971801A (en) * 2018-08-24 2018-12-11 华南理工大学 A kind of Ti-Zr-Ni-Fe-Cu-Co-Mo-B solder and the preparation method and application thereof
CN110355496A (en) * 2019-05-14 2019-10-22 中国航发北京航空材料研究院 A kind of high temperature resistant solder and soldering processes can be used for gamma-TiAl alloy
CN110666396A (en) * 2019-10-21 2020-01-10 中国航发北京航空材料研究院 Strip-shaped brazing material for titanium alloy medium-low temperature brazing, preparation method and brazing method

Also Published As

Publication number Publication date
CN111702278A (en) 2020-09-25

Similar Documents

Publication Publication Date Title
CN111702278B (en) Ti2Medium-temperature Ti-based brazing filler metal for brazing same or different AlNb-based alloys as well as preparation method and brazing process thereof
CN111702281B (en) Ti2Special intermediate-temperature Zr-based brazing filler metal for brazing same or different AlNb-based alloys as well as preparation method and brazing process thereof
CN111702280B (en) Ti2Medium-temperature Ti-based brazing filler metal special for brazing same or different AlNb-based alloy materials and preparation method and brazing process thereof
CN108971801B (en) Ti-Zr-Ni-Fe-Cu-Co-Mo-B brazing filler metal and preparation method and application thereof
CN106925906B (en) A kind of TiAl-base alloy special-purpose high temperature Ti-Zr base solder and preparation method thereof and soldering processes
CN103358051B (en) A kind of copper base solder and preparation method thereof
CN114346519B (en) Method for directly brazing TiAl alloy and Ti2AlNb alloy by using high-entropy brazing filler metal foil
CN101367159B (en) Cu-P based amorphous brazing filler metal and method for manufacturing the same
CN106925905B (en) A kind of TiAl-base alloy special-purpose high temperature Ti base solder and preparation method thereof and soldering processes
CN110605498B (en) TiNiNbZr high-temperature brazing filler metal for TiAl alloy, preparation method and brazing method thereof
EP1294528A1 (en) Method of brazing and article made therefrom
CN112975203B (en) Al-Si-Cu-Ni brazing filler metal for connecting Cu/Al joint and preparation method thereof
US4135656A (en) Nickel base brazing alloy
CN109604865B (en) Zirconium-based solder for connecting TiAl alloy and Ni-based high-temperature alloy
CN106392368A (en) High-temperature Zn-based soft solder for soldering aluminum and copper and welding method
CN110355496A (en) A kind of high temperature resistant solder and soldering processes can be used for gamma-TiAl alloy
CN111702277B (en) Ti2Medium-temperature Ti-based brazing filler metal special for brazing same or different AlNb-based alloy materials and preparation method and brazing process thereof
CN102642099A (en) Sn-Zn-based lead-free solder alloy for aluminum bronze soldering and method for preparing same
CN102814595A (en) Sn-Zn based near-eutectic lead-free solder alloy for aluminum-bronze soft soldering and preparation method
CN108453332B (en) Brazing process for vacuum brazing TiAl-based alloy by using amorphous Ti-Zr-Cu-Ni brazing filler metal
CN109465569A (en) A kind of high temperature brazing titanium based solder and preparation method
CN112719688A (en) Ti-Zr-Cu-Ni amorphous solder and preparation method and application thereof
CN109604861B (en) Iron-based solder for connecting TiAl alloy and Ni-based high-temperature alloy
CN105945447A (en) SnAgCu-series lead-free brazing filler metal and preparation method
CN109604866B (en) Solder for connecting TiAl alloy and Ni-based high-temperature alloy

Legal Events

Date Code Title Description
PB01 Publication
PB01 Publication
SE01 Entry into force of request for substantive examination
SE01 Entry into force of request for substantive examination
GR01 Patent grant
GR01 Patent grant