阅读说明：本技术 一种高能量密度加热焊接非晶合金的方法 (Method for heating and welding amorphous alloy with high energy density ) 是由 王成勇 陈伟专 唐梓敏 丁峰 王相煜 于 2021-07-30 设计创作，主要内容包括：本发明涉及非晶合金焊接技术领域,尤其涉及一种高能量密度加热焊接非晶合金的方法,包括S1、清洁待焊接的非晶合金板；S2、将待焊接的第一非晶合金板和待焊接的第二非晶合金板分别放置在第一平台内和第二平台上,支撑件支撑住第二非晶合金板；S3、将压辊和冷却装置调控至非晶合金待焊接的初始位置并贴住非晶合金板,将高能量密度装置的喷头指向非晶合金待焊接的初始位置,将温度传感器放置在非晶合金待焊接的初始位置,在主机系统上输入待焊接的非晶合金的型号；S4、启动主机系统；S5、将S4获得的非晶合金块体与其他非晶合金板重复进行S2～S4步骤,获得体积增加的非晶块体,该方法能快速准确地升温和快速冷却非晶合金焊接位。(The invention relates to the technical field of amorphous alloy welding, in particular to a method for heating and welding an amorphous alloy with high energy density, which comprises the steps of S1, cleaning an amorphous alloy plate to be welded; s2, respectively placing the first amorphous alloy plate to be welded and the second amorphous alloy plate to be welded in the first platform and on the second platform, and supporting the second amorphous alloy plate by the supporting piece; s3, regulating and controlling the pressing roller and the cooling device to the initial position to be welded of the amorphous alloy and attaching the pressing roller and the cooling device to the amorphous alloy plate, pointing the nozzle of the high-energy density device to the initial position to be welded of the amorphous alloy, placing the temperature sensor at the initial position to be welded of the amorphous alloy, and inputting the model of the amorphous alloy to be welded on the host system; s4, starting a host system; s5, repeating the steps S2-S4 on the amorphous alloy block obtained in the step S4 and other amorphous alloy plates to obtain the amorphous block with increased volume.)

1. A method for heating and welding amorphous alloy with high energy density is characterized in that: the high-energy-density welding system for the amorphous alloy comprises a first platform and a second platform, wherein the first platform and the second platform are aligned on a straight line, a supporting piece protruding upwards and used for supporting a second amorphous alloy plate is arranged on the upward end face of the second platform, and the outer end of the supporting piece is an elastic end;

the cooling device is attached to the position right below the welding end of the first amorphous alloy plate, the compression roller is attached to the position right above the welding end of the second amorphous alloy plate, and the cooling device and the compression roller can synchronously move along the welding moving path of the first amorphous alloy plate and the welding moving path of the second amorphous alloy plate;

a temperature sensor located at a position between the welding end of the first amorphous alloy plate and the welding end of the second amorphous alloy plate and movable along a welding moving path of the first amorphous alloy plate and the second amorphous alloy plate;

a high energy density device, wherein a nozzle of the high energy density device points to the position between the welding end of the first amorphous alloy plate and the welding end of the second amorphous alloy plate and can move;

the host system is connected with the cooling device, the compression roller, the temperature sensor and the spray head of the high-energy density device, the host system stores performance data of a plurality of amorphous alloy materials, and the host system controls the working states of the cooling device, the compression roller and the spray head of the high-energy density device according to the temperature measured by the temperature sensor;

when welding the amorphous alloy, the method comprises the following steps:

s1, cleaning the first amorphous alloy plate to be welded and the second amorphous alloy plate to be welded;

s2, respectively placing a first amorphous alloy plate to be welded and a second amorphous alloy plate to be welded in a first platform and on a second platform, wherein the support supports the second amorphous alloy plate, so that the welding end of the second amorphous alloy plate extends to the position above the welding end of the first amorphous alloy plate, and a spatial position is reserved between the welding end of the first amorphous alloy plate and the welding end of the second amorphous alloy plate;

s3, regulating and controlling the pressing roller and the cooling device to the initial position to be welded of the amorphous alloy and attaching the pressing roller and the cooling device to the amorphous alloy plate, pointing the nozzle of the high-energy density device to the initial position to be welded of the amorphous alloy, placing the temperature sensor at the initial position to be welded of the amorphous alloy, and inputting the model of the amorphous alloy to be welded on the host system;

s4, starting a host system, controlling a nozzle of the high-energy density device to gradually heat a connection interface of the amorphous alloy, simultaneously controlling a compression roller to gradually press the welding end of the second amorphous alloy plate on the welding end of the first amorphous alloy plate, and controlling a cooling device, a temperature sensor and the compression roller to synchronously move so that the first amorphous alloy plate is connected with the second amorphous alloy plate in a welding manner to obtain an amorphous alloy block;

and S5, repeating the steps from S2 to S4 on the amorphous alloy block obtained in S4 and other amorphous alloy plates to obtain an amorphous block with increased volume.

2. The method of high energy density heat welding amorphous alloy as claimed in claim 1, wherein: the side edges of the first platform and the second platform are respectively provided with a plurality of limiting pieces, the limiting pieces surround the first platform to form a first positioning space for placing a first amorphous alloy plate, and the limiting pieces surround the second platform to form a second positioning space for placing a second amorphous alloy plate.

3. The method of high energy density heat welding amorphous alloy as claimed in claim 2, wherein: the limiting part is a limiting column, and the circular surface of the limiting column points to the middle of the platform.

4. The method of high energy density heat welding amorphous alloy as claimed in claim 1, wherein: the supporting piece comprises a fixedly arranged pipe shell, a spring strip is arranged in the pipe shell, and the outer end of the spring strip extends out of the pipe shell and is fixed with an upward arched top cap.

5. The method of high energy density heat welding amorphous alloy as claimed in claim 1, wherein: the cooling device comprises a rib plate type cooling plate which can move along the lower side face of the welding end of the first amorphous alloy plate.

6. The method of high energy density heat welding amorphous alloy as claimed in claim 1, wherein: the high-energy density device comprises a mechanical arm, the spray head is connected to the mechanical arm, and the mechanical arm drives the spray head to move in multiple directions.

7. The method of high energy density heat welding amorphous alloy as claimed in claim 6, wherein: the mechanical arm is connected with the host system.

8. The method of high energy density heat welding amorphous alloy as claimed in claim 1, wherein: the device also comprises an inert gas nozzle which points to the side edge of the welding moving path of the first amorphous alloy plate and the second amorphous alloy plate and can move along the welding moving path of the first amorphous alloy plate and the second amorphous alloy plate.

9. The method of high energy density heat welding amorphous alloy as claimed in claim 8, wherein: the inert gas nozzle is connected to a guide rail in a sliding mode, and the guide rail is connected with the host system.

10. The method of high energy density heat welding amorphous alloy as claimed in claim 1, wherein: the energy of the high energy density device is one of a gas flame, a laser or an electron beam.

Technical Field

The invention relates to the technical field of amorphous alloy welding, in particular to a method for heating and welding an amorphous alloy with high energy density.

Background

Bulk amorphous alloys have received much attention because of their unique physical and chemical properties over traditional crystalline alloys, but the ability to form amorphous alloys is limited. The die-casting amorphous alloy needs extremely high cooling speed, and most of the amorphous alloy can only form the casting amorphous alloy of millimeter or centimeter grade under the current limited cooling speed; moreover, the amorphous alloy is easily crystallized at high temperature, which hinders the preparation of large-sized amorphous alloys.

At present, the preparation of large-size amorphous alloy by using an advanced manufacturing method is one of effective ways for solving the preparation problem of the large-size amorphous alloy, and the welding technology is a manufacturing process and a technology for jointing metal or other thermoplastic materials in a heating, high-temperature or high-pressure mode, and is suitable for welding the amorphous alloy formed by high-speed cooling. In recent years, a number of patents and related researches have been made on the application of welding techniques to join amorphous alloys, such as laser welding and electric current welding. The principle of the method is that the temperature of the alloy is raised to a supercooled liquid phase region by utilizing heat generated by laser or current, the amorphous alloy has superplasticity, and then the amorphous alloy is pressed, cooled and formed to finally realize the welding of the two amorphous alloys.

For example, in the invention creation with application number 201910621588.5, an amorphous alloy, a laser welding method thereof and a welding auxiliary device are disclosed, the method provides a laser welding method capable of cooling a part to be welded in a welding process, the method has the advantage of avoiding the problem of weld seam crystallization, but the method needs to artificially select laser parameters within a certain range to avoid crystallization before welding, which undoubtedly increases the difficulty and the accuracy of welding, and the laser parameters within the range are not necessarily suitable for welding other types of amorphous alloys, which seriously affects the welding quality of the amorphous alloy.

In the invention creation with application number 201911228983.3, an amorphous alloy vacuum welding device and method are disclosed, the method is provided with a welding platform in a vacuum cavity, and realizes the welding of the amorphous alloy by the vacuum laser welding technology in the vacuum environment, the method has the advantages of effectively avoiding the oxidation of the amorphous alloy and reducing air holes, but the method needs to manually adjust the welding parameters according to experience, and the cooling effect is poor, which is not beneficial to ensuring the complete amorphous state of the amorphous alloy welding process.

In the invention creation with application number 202011054489.2, an amorphous alloy resistance welding method is disclosed, the method utilizes the positive and negative poles of a direct current power supply to connect two amorphous alloys to be welded, the welding position is heated to a supercooled liquid phase region to generate plastic deformation, and then the amorphous alloys are connected together through the extrusion of a cylinder, and the method has the advantage that the problem that the welding connection performance is not ideal in the past can be solved. However, the method has the limitation of uncontrollable energy under the condition that the supercooling liquid phase regions of amorphous alloys made of different materials are different.

Disclosure of Invention

The invention aims to overcome the problems in the prior art and provides a method for heating and welding amorphous alloy with high energy density, which can quickly and accurately heat and quickly cool the welding position of the amorphous alloy so as to avoid the crystallization of the amorphous alloy.

In order to achieve the purpose, the invention adopts the following scheme:

provides a method for heating and welding amorphous alloy with high energy density, which comprises a high energy density welding system adopting amorphous alloy, the high energy density welding system for amorphous alloys comprises a first platform and a second platform, the first platform and the second platform are aligned on a straight line, the side edges of the first platform and the second platform are respectively provided with a plurality of limiting pieces, the limiting pieces surround the first platform to form a first positioning space for placing a first amorphous alloy plate, the limiting piece surrounds the second platform to form a second positioning space for placing a second amorphous alloy plate, the upward end surface of the second platform is provided with a supporting piece which protrudes upwards and is used for supporting the second amorphous alloy plate, the outer end of the supporting piece is an elastic end, and the welding end of the second amorphous alloy plate can extend above the welding end of the first amorphous alloy plate and can be connected with the welding end of the first amorphous alloy plate;

the cooling device is attached to the position right below the welding end of the first amorphous alloy plate, the compression roller is attached to the position right above the welding end of the second amorphous alloy plate, and the cooling device and the compression roller can synchronously move along the welding moving path of the first amorphous alloy plate and the welding moving path of the second amorphous alloy plate;

a temperature sensor located at a position between the welding end of the first amorphous alloy plate and the welding end of the second amorphous alloy plate and movable along a welding moving path of the first amorphous alloy plate and the second amorphous alloy plate;

a high energy density device, wherein a nozzle of the high energy density device points to the position between the welding end of the first amorphous alloy plate and the welding end of the second amorphous alloy plate and can move;

the host system is connected with the cooling device, the compression roller, the temperature sensor and the spray head of the high-energy density device, the host system stores performance data of a plurality of amorphous alloy materials, and the host system controls the working states of the cooling device, the compression roller and the spray head of the high-energy density device according to the temperature measured by the temperature sensor.

When welding the amorphous alloy, the method comprises the following steps:

s1, cleaning the first amorphous alloy plate to be welded and the second amorphous alloy plate to be welded;

s2, respectively placing a first amorphous alloy plate to be welded and a second amorphous alloy plate to be welded in a first platform and on a second platform, wherein the support supports the second amorphous alloy plate, so that the welding end of the second amorphous alloy plate extends to the position above the welding end of the first amorphous alloy plate, and a spatial position is reserved between the welding end of the first amorphous alloy plate and the welding end of the second amorphous alloy plate;

s3, regulating and controlling the pressing roller and the cooling device to the initial position to be welded of the amorphous alloy and attaching the pressing roller and the cooling device to the amorphous alloy plate, pointing the nozzle of the high-energy density device to the initial position to be welded of the amorphous alloy, placing the temperature sensor at the initial position to be welded of the amorphous alloy, and inputting the model of the amorphous alloy to be welded on the host system;

s4, starting a host system, controlling a nozzle of the high-energy density device to gradually heat a connection interface of the amorphous alloy, simultaneously controlling a compression roller to gradually press the welding end of the second amorphous alloy plate on the welding end of the first amorphous alloy plate, and controlling a cooling device, a temperature sensor and the compression roller to synchronously move so that the first amorphous alloy plate is connected with the second amorphous alloy plate in a welding manner to obtain an amorphous alloy block;

and S5, repeating the steps from S2 to S4 on the amorphous alloy block obtained in S4 and other amorphous alloy plates to obtain an amorphous block with increased volume.

The working principle of the method for heating and welding the amorphous alloy with high energy density is as follows: the high-energy density device comprises a first platform, a second platform, a cooling device and a first amorphous alloy plate, wherein the first platform is used for placing a first amorphous alloy plate to be welded, the second platform is used for placing a second amorphous alloy plate to be welded, the first amorphous alloy plate and the second amorphous alloy plate are arranged in a staggered mode in the vertical direction, so that the first amorphous alloy plate and the second amorphous alloy plate are provided with a staggered and overlapped area, a gap is reserved between the welding ends of the first amorphous alloy plate and the second amorphous alloy plate before the first amorphous alloy plate and the second amorphous alloy plate are not connected in the area, a nozzle of the high-energy density device gradually moves towards the gap so as to gradually heat the connection interface of the amorphous alloy plate to enable the connection interface to be converted into plastic rheology, a press roller rolls and presses the first amorphous alloy plate on the second amorphous alloy plate to enable the interfaces which are subjected to plastic rheology to be connected, and the cooling device instantly cools the welding parts which are connected together along with the movement.

The host system stores performance data of various amorphous alloy materials, corresponding amorphous alloy materials are selected in the host system, the host system calculates and controls output heating power according to a supercooling liquid phase area of the amorphous alloy to be welded, amorphous alloy crystallization is guaranteed, and meanwhile tedious work of finding optimized power by a traditional trial and error method is avoided. The temperature sensor monitors the heating temperature in real time and feeds monitored data back to the host system, so that the host system regulates and controls the compression roller, the cooling device and the like in real time, the temperature of the supercooled liquid phase region of the connection interface of the amorphous alloy is ensured, and the connection effect is ensured.

Further, a void is left between the first platform and the second platform, and the cooling device is placed in the void.

Furthermore, the limiting part is a limiting column, and the circular surface of the limiting column points to the middle of the platform.

Furthermore, the support piece comprises a fixedly arranged pipe shell, a spring strip is arranged in the pipe shell, and the outer end of the spring strip extends out of the pipe shell and is fixedly provided with an upward arched top cap.

Further, the cooling device comprises a rib plate type cooling plate which can move along the lower side face of the welding end of the first amorphous alloy plate.

Further, the high energy density device comprises a mechanical arm, the spray head is connected to the mechanical arm, and the mechanical arm drives the spray head to move in multiple directions.

Further, the robotic arm is coupled to the host system.

The device further comprises an inert gas nozzle, wherein the inert gas nozzle points to the side edge of the welding moving path of the first amorphous alloy plate and the second amorphous alloy plate and can move along the welding moving path of the first amorphous alloy plate and the second amorphous alloy plate.

Further, the inert gas nozzle is connected to a guide rail in a sliding mode, and the guide rail is connected with the host system.

Further, the energy of the high energy density device is one of a gas flame, a laser, or an electron beam.

Compared with the prior art, the invention has the following advantages:

(1) the compression roller and the cooling device move synchronously, and when the heating temperature rises to the expected temperature instantaneously, the purposes of heating while pressing and cooling are achieved, the effect of welding two amorphous plates into a whole is achieved, and the problem of crystallization is effectively avoided.

(2) The host system controls the temperature of the nozzle of the high-energy density device for heating the amorphous alloy according to the stored amorphous alloy parameters, controls the moving speed and the moving path of the compression roller and the cooling device through intelligent control, and controls the compression roller and the cooling device to move according to the temperature sensor, thereby not only ensuring the accuracy of the heating temperature, but also ensuring the synchronism of instantaneous heating and instantaneous cooling and avoiding the crystallization possibility of the amorphous alloy.

(3) The invention firstly welds and connects two amorphous alloy plates, and then repeatedly welds and connects the welded and connected amorphous alloy plates, thereby obtaining the amorphous alloy block with increased volume.

Drawings

The present application will be described in further detail with reference to the following drawings and detailed description.

FIG. 1 is a schematic diagram of a high energy density welding system for amorphous alloys of the present invention.

FIG. 2 is a schematic view of the pressing roller of the present invention in a state of pressing the second amorphous alloy sheet.

Fig. 3 is a flow chart of the operation of the temperature sensor with the host system and the heating system of the present invention.

Figure 4 is a schematic view of a robot arm and spray head of the present invention.

Fig. 5 is a schematic view showing a state where the second amorphous alloy sheet is press-fitted on the first amorphous alloy sheet by the pressing roller of the present invention.

The figure includes:

a first platform 1; a second platform 2; a limiting member 3; a first amorphous alloy plate 4; a second amorphous alloy plate 5; a support 6; a cooling device 7; a press roll 8; a temperature sensor 9; a high energy density device 10; a host system 11; a void 12; a tube shell 13; a spring bar 14; a top cap 15; a robotic arm 16; a guide rail 17; a weld end 18; a spray head 19; an energy line 20.

Detailed Description

The present application is further described with reference to the following examples in conjunction with the accompanying drawings.

Example 1

The method for heating and welding the amorphous alloy with high energy density disclosed in this embodiment adopts the amorphous alloy high energy density welding system shown in fig. 1, where the amorphous alloy high energy density welding system includes a first platform 1 and a second platform 2, the first platform 1 and the second platform 2 are aligned in a straight line, both sides of the first platform 1 and the second platform 2 are provided with a plurality of limiting members 3, the limiting members 3 surround the first platform 1 to form a first positioning space for placing a first amorphous alloy plate 4, the limiting members 3 surround the second platform 2 to form a second positioning space for placing a second amorphous alloy plate 5, an upward end surface of the second platform 2 is provided with a supporting member 6 protruding upward and used for supporting the second amorphous alloy plate 5, an outer end of the supporting member 6 is an elastic end, and a welding end 18 of the second amorphous alloy plate 5 can extend to a welding end 18 of the first amorphous alloy plate 4 The upper part of the first amorphous alloy plate can be connected with the welding end 18 of the first amorphous alloy plate 4;

the cooling device 7 and the compression roller 8 are attached to the position right below the welding end 18 of the first amorphous alloy plate 4, the compression roller 8 is attached to the position right above the welding end 18 of the second amorphous alloy plate 5, and the cooling device 7 and the compression roller 8 can synchronously move along the welding moving path of the first amorphous alloy plate 4 and the welding moving path of the second amorphous alloy plate 5;

a temperature sensor 9, said temperature sensor 9 being located at a position between the welding end 18 of said first amorphous alloy plate 4 and the welding end 18 of said second amorphous alloy plate 5 and being movable along the welding movement path of the first amorphous alloy plate 4 and the second amorphous alloy plate 5;

the high energy density device 10, as shown in the figure, the nozzle 19 of the high energy density device 10 is directed to a position between the welding end 18 of the first amorphous alloy plate 4 and the welding end 18 of the second amorphous alloy plate 5 and can move, and the energy line 20 is directed to the welding position.

The host system 11 is connected with the cooling device 7, the compression roller 8, the temperature sensor 9 and the nozzle 19 of the high energy density device 10, the host system 11 stores performance data of a plurality of amorphous alloy materials, and the host system 11 controls the working states of the cooling device 7, the compression roller 8 and the nozzle 19 of the high energy density device 10 according to the temperature measured by the temperature sensor 9. That is, as shown in fig. 3, the temperature sensor 9 measures the welding temperature and transmits the changed welding temperature data, the host system 11 compares the temperature measured by the temperature sensor 9 and controls the energy output power according to the temperature set by the host system 11 to form a closed loop system of detection-feedback-detection, regulates and controls the moving speed of the pressure roller 8 and the moving speed of the cooling device 7, ensures that the temperature is stabilized at the corresponding temperature of the supercooled liquid region, and realizes accurate temperature control and real-time control.

When welding the amorphous alloy, the method comprises the following steps:

s1, cleaning the first amorphous alloy plate 4 to be welded and the second amorphous alloy plate 5 to be welded, preferably, polishing by 400, 800 and 1200-mesh sand paper respectively to remove an oxide layer, soaking by absolute ethyl alcohol for ultrasonic cleaning for 3-5min, wiping by alcohol before welding to remove stains, and drying by an air duct;

s2, respectively placing a first amorphous alloy plate 4 to be welded and a second amorphous alloy plate 5 to be welded in a first platform 1 and on a second platform 2, wherein the second amorphous alloy plate 4 is supported by a support piece 6, so that a welding end 18 of the second amorphous alloy plate 5 extends to the position above the welding end 18 of the first amorphous alloy plate 4, and a space position is reserved between the welding end 18 of the first amorphous alloy plate 4 and the welding end 18 of the second amorphous alloy plate 5;

s3, regulating and controlling the pressure roller 8 and the cooling device 7 to the initial position to be welded of the amorphous alloy and attaching the amorphous alloy plate, pointing the nozzle 19 of the high-energy density device 10 to the initial position to be welded of the amorphous alloy, placing the temperature sensor 9 at the initial position to be welded of the amorphous alloy, and inputting the model of the amorphous alloy to be welded on the host system 11;

s4, starting a host system 11, wherein the host system 11 controls a spray head 19 of a high-energy density device 10 to gradually heat a connection interface of amorphous alloy, controls a compression roller to gradually press the welding end of a second amorphous alloy plate 5 onto the welding end of a first amorphous alloy plate 4, and controls a cooling device 7, a temperature sensor 9 and the compression roller 8 to synchronously move so that the first amorphous alloy plate 4 is in welding connection with the second amorphous alloy plate 5 to obtain an amorphous alloy block;

and S5, repeating the steps from S2 to S4 on the amorphous alloy block obtained in S4 and other amorphous alloy plates to obtain an amorphous block with increased volume.

The working principle of the method for heating and welding the amorphous alloy with high energy density is as follows: a first amorphous alloy plate 4 to be welded is placed in the positioning space of the first platform 1, a second amorphous alloy plate 5 to be welded is placed in the positioning space of the second platform 2, the first amorphous alloy plate 4 and the second amorphous alloy plate 5 are arranged in a staggered manner in the vertical direction, so that the first amorphous alloy plate 4 and the second amorphous alloy plate 5 have a staggered overlapped area, in which area, before the first amorphous alloy plate 4 and the second amorphous alloy plate 5 are not connected, the welding ends 18 of the amorphous alloy and the high-energy density device are provided with the vacant positions 12, the spray head 19 of the high-energy density device 10 moves gradually so as to gradually heat the connection interface of the amorphous alloy to convert the connection interface into plastic rheology, the press roller 8 rolls and presses the first amorphous alloy plate 4 on the second amorphous alloy plate 5 to connect the interfaces which generate the plastic rheology, and the cooling device 7 instantly cools the welding position along with the movement;

the host system 11 stores performance data of various amorphous alloy materials, corresponding amorphous alloy materials are selected in the host system 11, the host system 11 calculates and controls output heating power according to a supercooling liquid phase area of the amorphous alloy to be welded, complex work of finding optimized power by a traditional trial and error method is avoided while alloy is ensured to be not crystallized, the host system 11 controls a spray head 19 of a high-energy density device 10 to heat the amorphous alloy, and the host system 11 also controls a compression roller 8, a cooling device 7 and a temperature sensor 9 to synchronously move along a welding moving path, so that instantaneous heating and instantaneous cooling can be realized, and the heating and cooling are synchronously performed, thereby realizing the effects of quick temperature rise and quick cooling, being cooled and formed in time and avoiding the crystallization of the amorphous alloy; and the temperature sensor 9 monitors the heating temperature in real time, so that the temperature of the connection interface of the amorphous alloy reaching the supercooled liquid phase region is ensured, and the connection effect is ensured.

As shown in fig. 1, a vacant space 12 is left between the first stage 1 and the second stage 2, and the cooling device 7 is placed in the vacant space 12, so that the cooling device 7 can be easily placed.

As shown in fig. 1, the limiting member 3 is a limiting post, and a circular surface of the limiting post points to the middle of the platform. The end face of the limiting column is a plane, so that the amorphous alloy plate can be accurately positioned in the positioning space, and the clamping efficiency is improved.

As shown in fig. 2, the supporting member 6 includes a fixedly disposed pipe housing 13, a spring bar 14 is disposed in the pipe housing 13, and an outer end of the spring bar 14 extends out of the pipe housing 13 and is fixed with an upwardly arched top cap 15. The tube shell 13 can support the spring strips 14, and the spring strips 14 provide a buffer support function, so that the second amorphous alloy plate 5 can be supported, and the welding between the second amorphous alloy plate 5 and the first amorphous alloy plate 4 is not hindered.

As shown in fig. 1, the cooling device 7 comprises a cooling plate of a rib plate type, which is movable against the lower side of the welding tip 18 of the first amorphous alloy plate 4. The cooling device 7 can be a water-cooled cooling device 7, and the cooling plate can be made of brass, red copper and gold.

As shown in fig. 4, the high energy density apparatus 10 includes a robot arm 16, the spray head 19 is connected to the robot arm 16, and the robot arm 16 drives the spray head 19 to move in multiple directions. The robotic arm 16 is coupled to the host system 11. The host system 11 controls the movement path of the robot arm 16 and thus the welding movement path according to the measured parameters of the temperature sensor 9.

As shown in fig. 1, further comprises an inert gas nozzle (not shown) which is directed to the side of the welding moving path of the first amorphous alloy plate 4 and the second amorphous alloy plate 5 and can move along the welding moving path of the first amorphous alloy plate 4 and the second amorphous alloy plate 5. The inert gas nozzle provides inert gas with proper flow rate to avoid oxidation, and the inert gas protection duration is as follows: the problem of welding oxidation is effectively avoided from the beginning of welding to the end of cooling forming, inert gas is used for protection in the whole welding process, oxidation reaction of air and high-temperature molten alloy is effectively avoided, and the purity of the amorphous alloy is guaranteed. The inert gas may be argon or helium.

As shown in fig. 1, the inert gas nozzle is slidably connected to a guide rail 17, and the guide rail 17 is connected to the host system 11. The guide rail 17 facilitates the movement of the inert gas nozzle.

In this embodiment, the energy of the high energy density device 10 is one of a gas flame, a laser, or an electron beam. The heating mode with high energy density can lead the alloy to be heated up instantly, and the welding speed is 50mm/s, thus having higher welding efficiency.

Example 2

The difference between this embodiment and embodiment 1 is that, in order to achieve the effect of moving the cooling device and the pressure roller, the first platform and the second platform are configured to be movable, so that the cooling device and the pressure roller can move synchronously, and the first platform and the second platform are connected to the host system and can move synchronously, and other structures are the same as those in embodiment 1 and are not described herein again.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present application, and not for limiting the protection scope of the present application, and although the present application is described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions can be made on the technical solutions of the present application without departing from the spirit and scope of the technical solutions of the present application.