CN114054752A - High-temperature metallurgy sintering device - Google Patents

Abstract

The invention relates to the technical field of metallurgical sintering, and discloses a high-temperature metallurgical sintering device which comprises an operation table, a sintering frame, a lifting plate, a mounting groove and an air inlet pipe, wherein the operation table is arranged on the operation table; the sintering frame is fixed on the top surface of operation panel, and the sintering frame transversely arranges the top surface of operation panel in, and the sintering frame is located the surface middle part of operation panel, and the front end middle part surface mounting of sintering frame has the industrial computer, the equal vertical electric putter of installing in the surperficial both sides of sintering frame, electric putter's below runs through to the inside of sintering frame. According to the invention, the four high-frequency tubes are arranged in the sintering frame and can be synchronously driven to descend and rise, and after an original piece enters the sintering frame, the original piece can be sequentially heated by the high-frequency tubes with gradually increased tube diameters, so that a more uniform and high-quality heating effect is obtained.

Description

High-temperature metallurgy sintering device

Technical Field

The invention relates to the technical field of metallurgical sintering, in particular to a high-temperature metallurgical sintering device.

Background

At present, sintering refers to a process in which solid powder is shaped and then heated to a certain temperature to begin to shrink and densify, and finally a compact and solid whole is formed.

However, unlike the conventional heating method, the high-frequency induction heating also has problems such as: when heating the original paper, high frequency induction heating's induction heating scope is less, exists the uneven condition of original paper heating easily, and is not good to original paper intensification heating effect during the heating, finally leads to being not good to the sintering effect of metal original paper. Therefore, we propose a pyrometallurgical sintering device.

Disclosure of Invention

The invention aims to provide a high-temperature metallurgy sintering device, which is characterized in that four high-frequency tubes are arranged in a sintering frame and can be synchronously driven to descend and ascend, an original piece can be sequentially heated by the high-frequency tubes with gradually-increased tube diameters after entering the sintering frame, and a more uniform and high-quality heating effect is further obtained.

In order to achieve the purpose, the invention provides the following technical scheme: a high-temperature metallurgy sintering device comprises an operation table, a sintering frame, a lifting plate, a mounting groove and an air inlet pipe; the sintering frame is fixed on the upper surface of the operating platform, the sintering frame is transversely arranged on the upper surface of the operating platform, the sintering frame is positioned in the middle of the surface of the operating platform, and an industrial computer is arranged on the surface of the middle of the front end of the sintering frame;

electric push rods are vertically arranged on two sides of the surface of the sintering frame, the lower portions of the electric push rods penetrate into the sintering frame, belt grooves are formed in the lower portions of the right side and the lower portions of the left side of the sintering frame, and the belt grooves are communicated with the interior of the sintering frame;

the lifting plate is transversely arranged on the left side in the sintering frame and parallel to the surface of the operating platform, the upper surface of the lifting plate is fixed at the bottom of the electric push rod, a first high-frequency tube is mounted on the lower surface of the right side of the lifting plate through a mounting seat, a second high-frequency tube is mounted on the lower surface of the lifting plate on the left side of the first high-frequency tube through the mounting seat, a third high-frequency tube is mounted on the lower surface of the lifting plate on the left side of the second high-frequency tube through the mounting seat, a fourth high-frequency tube is mounted on the lower surface of the lifting plate on the left side of the third high-frequency tube through the mounting seat, the distances between the adjacent mounting seats are equal, and the diameters of the first high-frequency tube, the second high-frequency tube, the third high-frequency tube and the fourth high-frequency tube are sequentially increased;

the mounting groove is transversely formed in the middle surface of the operating table, the middle position of the mounting groove penetrates through the surface of the operating table below the interior of the sintering frame, the conveying belt is mounted inside the mounting groove and penetrates through the inner side of the sintering frame through a belt groove, a plurality of ceramic plates are fixed on the surface of the conveying belt and are uniformly distributed on the surface of the conveying belt, and the distance between every two adjacent ceramic plates is equal to the distance between every two adjacent mounting seats;

the vertical connection of intake pipe is on the sintering frame surface between the electric putter of both sides, and the below of intake pipe runs through to the inside of sintering frame, and is adjacent the vertical connecting pipe that is fixed with in lifter plate below between the mount pad, the connecting pipe passes through hose and the inside intercommunication of intake pipe, and the left side and the right side of connecting pipe are all connected with the blowing pipe to one side, and the inside intercommunication of blowing pipe and connecting pipe.

As a preferred embodiment of the present invention, an electromagnetic heating tube is embedded and fixed below the inner portion of the ceramic plate, the electromagnetic heating tube is spirally disposed inside the ceramic plate, and the electromagnetic heating tube is electrically connected to an industrial computer.

As a preferred embodiment of the present invention, the ceramic plate has a groove formed on an upper surface thereof, and the groove is located on a surface of the ceramic plate above the electromagnetic heating pipe.

In a preferred embodiment of the present invention, the side surface of the sintering frame above the belt groove is provided with a through hole, the through hole is located at a middle position above the belt groove, and the through hole is communicated with the belt groove.

In a preferred embodiment of the present invention, four support legs are supported and fixed at four corners of the lower portion of the operating table, and four support legs are provided.

In a preferred embodiment of the present invention, a servo motor is installed on a front surface of the right side of the operation table, the servo motor is in transmission connection with the conveyor belt, and the servo motor is electrically connected with the industrial computer.

In a preferred embodiment of the present invention, a flange is connected to an upper end of the intake pipe, and an inner ring of the flange communicates with an inside of the intake pipe.

In a preferred embodiment of the present invention, the intake pipe is provided with a valve, and the valve is communicated with the inside of the intake pipe.

Compared with the prior art, the invention has the following beneficial effects:

1. according to the high-temperature metallurgy sintering device, the four high-frequency tubes are arranged in the sintering frame and can be synchronously driven to descend and ascend, and after an original piece enters the sintering frame, the original piece can be sequentially heated by the high-frequency tubes with gradually-increased tube diameters, so that a more uniform and high-quality heating effect is obtained.

2. According to the high-temperature metallurgy sintering device, the electromagnetic heating pipe is embedded and fixed in the lower portion of the interior of the ceramic plate, the electromagnetic heating pipe is spirally arranged in the ceramic plate and electrically connected with the industrial personal computer, and through the arrangement of the electromagnetic heating pipe, a heating effect can be provided for the bottom of an original piece, so that the original piece is heated more fully.

3. According to the high-temperature metallurgy sintering device, the grooves are formed in the upper surface of the ceramic plate and are positioned on the surface of the ceramic plate above the electromagnetic heating pipe, and the original piece can be stably placed on the surface of the ceramic plate through the grooves.

4. According to the high-temperature metallurgy sintering device, the side surface of the sintering frame above the belt groove is provided with the through hole, the through hole is positioned in the middle position above the belt groove and is communicated with the belt groove, and the original piece is carried by the ceramic plate to enter from the through hole through the through hole.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic view of the entire structure of a pyrometallurgical sintering apparatus of the present invention;

FIG. 2 is a schematic diagram of the internal structure of a sintering frame of the pyrometallurgical sintering apparatus of the present invention;

FIG. 3 is a schematic view showing the structure of a ceramic plate of the pyrometallurgical sintering apparatus of the present invention;

FIG. 4 is a schematic cross-sectional view of a ceramic plate for a pyrometallurgical sintering apparatus in accordance with the present invention.

In the figure: 1. an operation table; 2. sintering the frame; 3. a lifting plate; 4. mounting grooves; 5. an air inlet pipe; 6. a flange; 7. an electric push rod; 8. a belt groove is formed; 9. a port; 10. a conveyor belt; 11. a ceramic plate; 12. a servo motor; 13. an industrial control computer; 14. a support leg; 15. a hose; 16. a first high-frequency tube; 17. a second high-frequency tube; 18. a third high frequency tube; 19. a fourth high-frequency tube; 20. a connecting pipe; 21. a blowpipe; 22. a groove; 23. an electromagnetic heating pipe; 24. a valve; 25. and (7) mounting a seat.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "disposed" are to be construed broadly, e.g., as meaning fixedly connected, disposed, detachably connected, disposed, or integrally connected and disposed; the type of the electrical appliance provided by the invention is only used for reference. For those skilled in the art, different types of electrical appliances with the same function can be replaced according to actual use conditions, and for those skilled in the art, the specific meaning of the above terms in the present invention can be understood in specific situations.

Referring to fig. 1-4, the present invention provides a technical solution: a high-temperature metallurgy sintering device comprises an operation platform 1, a sintering frame 2, a lifting plate 3, a mounting groove 4 and an air inlet pipe 5; the sintering frame 2 is fixed on the upper surface of the operating platform 1, the sintering frame 2 is transversely arranged on the upper surface of the operating platform 1, the sintering frame 2 is positioned in the middle of the surface of the operating platform 1, and an industrial computer 13 is arranged on the surface of the middle of the front end of the sintering frame 2;

electric push rods 7 are vertically arranged on two sides of the surface of the sintering frame 2, the lower portions of the electric push rods 7 penetrate into the sintering frame 2, belt grooves 8 are formed in the lower portions of the right side and the left side of the sintering frame 2, and the belt grooves 8 are communicated with the inside of the sintering frame 2;

the lifting plate 3 is transversely arranged on the left side in the sintering frame 2, the lifting plate 3 is parallel to the surface of the operating platform 1, the upper surface of the lifting plate 3 is fixed at the bottom of the electric push rod 7, a first high-frequency tube 16 is arranged on the lower surface of the right side of the lifting plate 3 through an installation seat 25, a second high-frequency tube 17 is arranged on the lower surface of the lifting plate 3 on the left side of the first high-frequency tube 16 through the installation seat 25, a third high-frequency tube 18 is arranged on the lower surface of the lifting plate 3 on the left side of the second high-frequency tube 17 through the installation seat 25, a fourth high-frequency tube 19 is arranged on the lower surface of the lifting plate 3 on the left side of the third high-frequency tube 18 through the installation seat 25, the distances between the adjacent installation seats 25 are equal, and the tube diameters of the first high-frequency tube 16, the second high-frequency tube 17, the third high-frequency tube 18 and the fourth high-frequency tube 19 are sequentially increased;

the installation groove 4 is transversely formed in the middle surface of the operation table 1, the middle position of the installation groove 4 penetrates through the surface of the operation table 1 below the inner part of the sintering frame 2, the conveying belt 10 is installed inside the installation groove 4, the conveying belt 10 penetrates through the inner side of the sintering frame 2 through the belt groove 8, ceramic plates 11 are fixed on the surface of the conveying belt 10, the ceramic plates 11 are arranged in a plurality, the ceramic plates 11 are uniformly distributed on the surface of the conveying belt 10, and the distance between every two adjacent ceramic plates 11 is equal to the distance between every two adjacent installation seats 25;

the vertical sintering frame 2 surface of connecting between both sides electric putter 7 of intake pipe 5, and the below of intake pipe 5 runs through to the inside of sintering frame 2, and is adjacent the vertical connecting pipe 20 that is fixed with in lifter plate 3 below between the mount pad 25, connecting pipe 20 pass through the inside intercommunication of hose 15 and intake pipe 5, and the left side and the right side of connecting pipe 20 are all connected with blowing pipe 21 to one side, and the inside intercommunication of blowing pipe 21 and connecting pipe 20.

In the invention, a manipulator is respectively arranged at the left side and the right side of an operating platform 1 and used for feeding and discharging, an air inlet pipe 5 is connected to a shielding gas supply device, a high-frequency electric heating pipe is connected to a high-frequency generator and is connected with an industrial personal computer 13, an electric push rod 7 is also connected to the industrial personal computer 13, the industrial personal computer 13 is connected to a power supply, the industrial personal computer 13 can control each device, a conveyor belt 10 and a high-frequency heater are started through the industrial personal computer 13 to drive a ceramic plate 11 to convey towards the left side, in the conveying process, the manipulator places an original piece to be sintered on the ceramic plate 11 on the surface of a right conveyor belt 10, the conveyor belt 10 and the ceramic plate 11 drive the original piece to move towards the inside of a sintering frame 2 and are arranged below a first high-frequency pipe 16, the conveyor belt 10 temporarily conveys the original piece, then the electric push rod 7 drives a lifting plate 3 to descend to the outer ring of the original piece 16, the original is subjected to preliminary high-frequency heating, then the lifting plate 3 is driven to rise, the conveying belt 10 continues to drive the ceramic plate 11 and the original to move towards the left side to the position below the second high-frequency pipe 17, then the lifting plate 3 drives the second high-frequency pipe 17 to fall again, the original is further subjected to high-frequency heating through the second high-frequency pipe 17, then the operation is continuously repeated, so that the original is heated through the third high-frequency pipe 18 and the fourth high-frequency pipe 19, in the heating process, the protective gas enters the connecting pipe 20 through the air inlet pipe 5 and the hose 15 and is blown out from the air blowing pipe 21 into the sintering frame 2, the effect of the protective gas can be provided for the original during sintering, the influence on the quality of the original due to oxidation reaction at high temperature is avoided, the first high-frequency pipe 16, the second high-frequency pipe 17, the third high-frequency pipe 18 and the fourth high-frequency pipe 19 can gradually increase the heating intensity to heat the original, and first high-frequency tube 16, second high-frequency tube 17, third high-frequency tube 18 and fourth high-frequency tube 19 heat in proper order and can guarantee that the original paper is heated more evenly and obtain better heating effect, have guaranteed the sintering effect, and the original paper that the sintering was accomplished is discharged from the left side, is taken out by the manipulator centre gripping.

In an optional embodiment, an electromagnetic heating pipe 23 is fixedly embedded in the lower portion of the inside of the ceramic plate 11, the electromagnetic heating pipe 23 is spirally disposed in the ceramic plate 11, and the electromagnetic heating pipe 23 is electrically connected to the industrial computer 13, in this embodiment (see fig. 4), the electromagnetic heating pipe 23 is fixedly embedded in the lower portion of the inside of the ceramic plate 11, the electromagnetic heating pipe 23 is spirally disposed in the ceramic plate 11, and the electromagnetic heating pipe 23 is electrically connected to the industrial computer 13, and by means of the arrangement of the electromagnetic heating pipe 23, a heating effect can be provided for the bottom of an original, so that the original can be heated more sufficiently.

In an alternative embodiment, the upper surface of the ceramic plate 11 is provided with the groove 22, and the groove 22 is located on the surface of the ceramic plate 11 above the electromagnetic heating tube 23, in this embodiment (see fig. 3), the groove 22 is formed on the upper surface of the ceramic plate 11, and the groove 22 is located on the surface of the ceramic plate 11 above the electromagnetic heating tube 23, and the arrangement of the groove 22 enables the original to be placed on the surface of the ceramic plate 11 more stably.

In an alternative embodiment, the side surface of the sintering frame 2 above the belt groove 8 is provided with a through hole 9, the through hole 9 is located at a middle position above the belt groove 8, and the through hole 9 is communicated with the belt groove 8, in this embodiment (see fig. 1), the side surface of the sintering frame 2 above the belt groove 8 is provided with the through hole 9, the through hole 9 is located at a middle position above the belt groove 8, the through hole 9 is communicated with the belt groove 8, and the through hole 9 is arranged to enable the original to be carried by the ceramic plate 11 to enter from the through hole 9.

In an alternative embodiment, four support legs 14 are supported and fixed at four corners of the lower portion of the operation table 1, and four support legs 14 are provided, in this embodiment (see fig. 1), the operation table 1 is stably supported by the support legs 14.

In an alternative embodiment, a servo motor 12 is installed on the front end surface of the right side of the operating platform 1, the servo motor 12 is in transmission connection with the conveyor belt 10, and the servo motor 12 is electrically connected with an industrial computer 13, in this embodiment (see fig. 1), the transmission of the conveyor belt 10 is realized through the servo motor 12, and is controlled by the industrial computer 13.

In an alternative embodiment, a flange 6 is connected to an upper end of the air inlet pipe 5, and an inner ring of the flange 6 is communicated with an inside of the air inlet pipe 5, in this embodiment (see fig. 1), the air inlet pipe 5 is connected to a supply device of shielding gas through the flange 6.

In an alternative embodiment, a valve 24 is installed on the intake pipe 5, and the valve 24 is communicated with the inside of the intake pipe 5, in this embodiment (refer to fig. 2), the opening state of the intake pipe 5 is controlled by the valve 24.

It should be noted that the present invention is a pyrometallurgical sintering device, which includes an operation table 1, a sintering frame 2, a lifting plate 3, an installation groove 4, an air inlet pipe 5, a flange 6, an electric push rod 7, a belt groove 8, a port 9, a conveyor belt 10, a ceramic plate 11, a servo motor 12, an industrial computer 13, a support leg 14, a hose 15, a first high-frequency pipe 16, a second high-frequency pipe 17, a third high-frequency pipe 18, a fourth high-frequency pipe 19, a connection pipe 20, a blowing pipe 21, a groove 22, an electromagnetic heating pipe 23, a valve 24, and an installation seat 25, all of which are common standard components or components known to those skilled in the art, and the structure and principle of which are known to those skilled in the art or known to those skilled in the art through conventional experimental methods, in the spare part of the present device, all of the above electric devices, which refer to a power element, an electric device, and an adapted monitoring computer, are connected through a wire, the detailed connection means is a known technology in the art, and the above mainly introduces the working principle and process, and does not describe the electrical control.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (8)

1. A high-temperature metallurgy sintering device is characterized by comprising an operation table (1), a sintering frame (2), a lifting plate (3), a mounting groove (4) and an air inlet pipe (5); the sintering frame (2) is fixed on the upper surface of the operating platform (1), the sintering frame (2) is transversely arranged on the upper surface of the operating platform (1), the sintering frame (2) is positioned in the middle of the surface of the operating platform (1), and an industrial computer (13) is arranged on the surface of the middle of the front end of the sintering frame (2);

electric push rods (7) are vertically arranged on two sides of the surface of the sintering frame (2), the lower portions of the electric push rods (7) penetrate through the sintering frame (2), belt grooves (8) are formed in the lower portions of the right side and the left side of the sintering frame (2), and the belt grooves (8) are communicated with the inside of the sintering frame (2);

the lifting plate (3) is transversely arranged on the left side inside the sintering frame (2), the lifting plate (3) is parallel to the surface of the operation table (1), the upper surface of the lifting plate (3) is fixed at the bottom of the electric push rod (7), a first high-frequency tube (16) is installed on the lower surface of the right side of the lifting plate (3) through a mounting seat (25), a second high-frequency tube (17) is installed on the lower surface of the left lifting plate (3) of the first high-frequency tube (16) through the mounting seat (25), a third high-frequency tube (18) is installed on the lower surface of the left lifting plate (3) of the second high-frequency tube (17) through the mounting seat (25), a fourth high-frequency tube (19) is installed on the lower surface of the left lifting plate (3) of the third high-frequency tube (18) through the mounting seat (25), the distances between the adjacent mounting seats (25) are equal, the first high-frequency tube (16), the second high-frequency tube (17), The pipe diameters of the third high-frequency pipe (18) and the fourth high-frequency pipe (19) are sequentially increased;

the ceramic plate conveying device is characterized in that the installation groove (4) is transversely formed in the surface of the middle of the operating table (1), the middle of the installation groove (4) penetrates through the surface of the operating table (1) below the interior of the sintering frame (2), the conveying belt (10) is installed inside the installation groove (4), the conveying belt (10) penetrates through the inner side of the sintering frame (2) through the belt groove (8), a plurality of ceramic plates (11) are fixed on the surface of the conveying belt (10), the ceramic plates (11) are uniformly distributed on the surface of the conveying belt (10), and the distance between every two adjacent ceramic plates (11) is equal to that between every two adjacent installation seats (25);

intake pipe (5) vertical connection is on sintering frame (2) surface between both sides electric putter (7), and the below of intake pipe (5) runs through to the inside of sintering frame (2), and is adjacent the vertical connecting pipe (20) that is fixed with in lifter plate (3) below between mount pad (25), connecting pipe (20) are through hose (15) and the inside intercommunication of intake pipe (5), and the equal slant in left side and the right side of connecting pipe (20) is connected with blowing pipe (21), and the inside intercommunication of blowing pipe (21) and connecting pipe (20).

2. A pyrometallurgical sintering device in accordance with claim 1, wherein: the embedded electromagnetic heating pipe (23) is fixed to the inside below of ceramic plate (11), and inside the electromagnetic heating pipe (23) were arranged in ceramic plate (11) in the spiral, and electromagnetic heating pipe (23) and industrial computer (13) electric connection.

3. A pyrometallurgical sintering device in accordance with claim 2, wherein: the upper surface of the ceramic plate (11) is provided with a groove (22), and the groove (22) is positioned on the surface of the ceramic plate (11) above the electromagnetic heating pipe (23).

4. A pyrometallurgical sintering device in accordance with claim 1, wherein: through hole (9) have been seted up to sintering frame (2) side surface of trough of belt (8) top, and through hole (9) are located the middle part position of trough of belt (8) top, and through hole (9) and trough of belt (8) intercommunication.

5. A pyrometallurgical sintering device in accordance with claim 1, wherein: supporting legs (14) are fixedly supported at four corners below the operating platform (1), and four supporting legs (14) are arranged.

6. A pyrometallurgical sintering device in accordance with claim 1, wherein: the surface of the front end of the right side of the operating platform (1) is provided with a servo motor (12), the servo motor (12) is in transmission connection with the conveyor belt (10), and the servo motor (12) is electrically connected with the industrial computer (13).

7. A pyrometallurgical sintering device in accordance with claim 1, wherein: the upper end of the air inlet pipe (5) is connected with a flange (6), and the inner ring of the flange (6) is communicated with the inside of the air inlet pipe (5).

8. A pyrometallurgical sintering device in accordance with claim 1, wherein: install valve (24) on intake pipe (5), and valve (24) and intake pipe (5) inside intercommunication.

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