CN112892382A - Pushi alloy furnace roller dosing unit - Google Patents

Abstract

The invention discloses a pu's alloy furnace roller batching device, which belongs to the technical field of alloy furnace roller batching, and particularly relates to a pu's alloy furnace roller batching device, which comprises a high-temperature reaction kettle, wherein pushing structures are fixedly arranged on two sides of the high-temperature reaction kettle, a first valve is fixedly arranged at the top end of each pushing structure, batching structures are fixedly arranged on two sides of the high-temperature reaction kettle, each batching structure comprises a first batching bin, a first batching bin is fixedly arranged on one side of the high-temperature reaction kettle, and a second batching bin is fixedly arranged on one side of the high-temperature reaction kettle, which is far away from the first batching bin, the pu's alloy: the size ratio of the space among the first isolation bin, the second isolation bin, the third isolation bin, the fourth isolation bin and the fifth isolation bin is 1:2:3:4:5, different materials are transmitted into the isolation bins according to the required ratio by controlling the third valve on the main pipe and the second valve on each connecting pipe, and the materials are proportioned according to the required ratio, so that the working efficiency is improved.

Description

Pushi alloy furnace roller dosing unit

Technical Field

The invention relates to the technical field of alloy furnace roller batching, in particular to a pu's alloy furnace roller batching device.

Background

The alloy is a solid product with metal property obtained by mixing and melting one metal and another metal or nonmetal, cooling and solidifying, and the mixing and melting of one metal and another metal or nonmetal are carried out by batching.

The prior art has the following defects: the existing batching device can not control the required proportion during batching, can not enable incomplete fusion in the alloy without other equipment, can not reach the required strength for the hardness and the toughness of the manufactured product, can reduce the working efficiency with the help of other equipment, and can influence the working process.

Therefore, the invention is necessary to invent a pu's alloy furnace roller batching device.

Disclosure of Invention

Therefore, the invention provides a pu's alloy furnace roller batching device, which is characterized in that the space size ratio among a first isolation bin, a second isolation bin, a third isolation bin, a fourth isolation bin and a fifth isolation bin is 1:2:3:4:5, and different materials are transmitted into the isolation bins according to the required ratio by controlling a third valve on a main pipe and a second valve on each connecting pipe, so that the problem that the batching can not be carried out according to the required ratio by the conventional device is solved.

In order to achieve the above purpose, the invention provides the following technical scheme: a pu's alloy furnace roller batching device comprises a high-temperature reaction kettle, wherein both sides of the high-temperature reaction kettle are fixedly provided with a material pushing structure, the top end of the material pushing structure is fixedly provided with a first valve, both sides of the high-temperature reaction kettle are fixedly provided with batching structures, each batching structure comprises a first batching bin, one side of the high-temperature reaction kettle is fixedly provided with a first batching bin, one side of the high-temperature reaction kettle, which is far away from the first batching bin, is fixedly provided with a second batching bin, the bottom ends of the first batching bin and the second batching bin are fixedly connected with the first valve, each of the first batching bin and the second batching bin comprises a first isolation bin, one side of the first isolation bin is fixedly provided with a second isolation bin, one side of the second isolation bin, which is far away from the first isolation bin, is fixedly provided with a third isolation bin, one side of the third isolation bin, which is far away from the second isolation bin, a fifth isolation bin is fixedly installed on one side, away from the third isolation bin, of the fourth isolation bin, and the size ratio of the spaces among the first isolation bin, the second isolation bin, the third isolation bin, the fourth isolation bin and the fifth isolation bin is 1:2:3:4: and 5, the top ends of the first isolation bin, the second isolation bin, the third isolation bin, the fourth isolation bin and the fifth isolation bin are respectively and fixedly connected with a first connecting pipe, a second connecting pipe, a third connecting pipe, a fourth connecting pipe and a fifth connecting pipe, the top ends of the first connecting pipe, the second connecting pipe, the third connecting pipe, the fourth connecting pipe and the fifth connecting pipe are respectively and fixedly connected with a main pipe, a first feeding port is fixedly arranged at the top end of the main pipe on the first proportioning bin, and a second feeding port is fixedly arranged at the top end of the main pipe on the second proportioning bin.

Preferably, the top ends and the bottom ends of the first connecting pipe, the second connecting pipe, the third connecting pipe, the fourth connecting pipe and the fifth connecting pipe are all fixedly provided with second valves, and the main pipe is fixedly provided with third valves.

Preferably, the material pushing structure comprises a material pushing box, a discharge port is formed in one side of the material pushing box, the discharge port is fixedly connected with the high-temperature reaction kettle, a motor is fixedly mounted on one side, away from the discharge port, of the material pushing box, and the output end of the motor extends to a packing auger fixedly connected with the inside of the material pushing box.

Preferably, an arc-shaped isolation plate is fixedly installed in the high-temperature reaction kettle, and a mixing structure is arranged above the arc-shaped isolation plate.

Preferably, the mixed structure includes the second motor, high temperature reaction cauldron top fixed mounting has the second motor, second motor output end fixed connection has the dwang, dwang bottom and arc division board swing joint, fixed mounting has arc mixing plate on the dwang, the second discharge gate has been seted up to arc mixing plate bottom.

Preferably, a high-temperature fusion bin is arranged below the high-temperature reaction kettle.

Preferably, the material pushing structure further comprises an electric telescopic rod and a push plate, the bottom end of the electric telescopic rod is fixedly connected with one side, away from the discharge port, of the material pushing box, the top end of the electric telescopic rod is fixedly connected with the push plate, and the push plate is movably connected with the material pushing box.

A puh alloy furnace roller batching method further comprises the following specific steps:

the method comprises the following steps: taking aluminum particles, copper particles, silicon particles, magnesium particles, zinc particles and manganese powder;

step two: the ratio of aluminum particles, copper particles, silicon particles, magnesium particles, zinc particles and manganese powder required for preparing the required alloy is 9: 1: 3: 2: 1: 2;

step three: aluminum particles, copper particles, silicon particles and magnesium particles are sequentially led into a main pipe on a first proportioning bin through a first feeding port, a third valve on the main pipe and a second valve on a first connecting pipe, a second connecting pipe, a third connecting pipe, a fourth connecting pipe and a fifth connecting pipe are controlled, the aluminum particles are led into a fourth isolation bin and a fifth isolation bin through the fourth connecting pipe and the fifth connecting pipe, the copper particles are led into the first isolation bin through the first connecting pipe, the silicon particles are led into the third isolation bin through the third connecting pipe, the magnesium particles are led into the second isolation bin through the second connecting pipe, zinc particles and manganese powder are sequentially led into a main pipe on a second proportioning bin through a second feeding port, a third valve on the main pipe and a second valve on the first connecting pipe, the second connecting pipe and a second valve on the main pipe are controlled, and the zinc particles are led into the first isolation bin on the second proportioning bin through the first connecting pipe, guiding manganese powder into a second isolation bin on a second batching bin through a second connecting pipe;

step four: controlling a first valve to pour materials in a first isolation bin, a second isolation bin, a third isolation bin, a fourth isolation bin and a fifth isolation bin in a first batching bin and materials in the first isolation bin and the second isolation bin in a second batching bin into a material pushing box;

step five: opening a motor to drive a packing auger to guide the materials in the material pushing box into the high-temperature reaction kettle through a discharge port, and opening a second motor to drive an arc-shaped isolation plate to mix the materials;

step six: the mixture is led into a high-temperature fusion bin through a second discharge hole and is melted and fused at high temperature;

step seven: and after the fusion is finished, the mixture is led out of the high-temperature reaction kettle to be poured into a pu's alloy furnace roller.

The invention has the beneficial effects that:

1. different materials are conveyed into the first proportioning bin, the first separating bin, the second separating bin, the third separating bin, the fourth separating bin and the fifth separating bin on the second proportioning bin according to the required proportion by controlling a third valve on the main pipe and second valves on the first connecting pipe, the second connecting pipe, the third connecting pipe, the fourth connecting pipe and the fifth connecting pipe, and the working efficiency is improved by proportioning the materials according to the required proportion;

2. through with second motor fixed mounting at high temperature reation kettle, second motor output extends to high temperature reation kettle in, with dwang fixed connection, with arc mixing plate and dwang fixed connection, mixes the material that comes through the arc mixing plate to the transmission for melt when fusing more even, promote alloy product quality.

Drawings

FIG. 1 is a front view provided by the present invention;

FIG. 2 is a cross-sectional view provided by the present invention;

FIG. 3 is an enlarged view of the high temperature reaction vessel provided by the present invention;

FIG. 4 is an enlarged view of the dispensing structure provided by the present invention;

FIG. 5 is a schematic diagram of a material pushing structure according to embodiment 1 of the present invention;

fig. 6 is a structure diagram of a material pushing device in embodiment 2.

In the figure: the high-temperature reaction kettle comprises a high-temperature reaction kettle 1, an arc-shaped isolation plate 11, a mixing structure 12, a second motor 121, a rotating rod 122, an arc-shaped plate mixing plate 123, a second discharge hole 124, a high-temperature fusion bin 13, a material pushing structure 2, a material pushing box 21, a discharge hole 211, a motor 22, an auger 23, an electric telescopic rod 24, a push plate 25, a first valve 3, a batching structure 4, a first batching bin 41, a second batching bin 42, a first isolation bin 43, a second isolation bin 44, a third isolation bin 45, a fourth isolation bin 46, a fifth isolation bin 47, a first connecting pipe 431, a second connecting pipe 441, a third connecting pipe 451, a fourth connecting pipe 461, a fifth connecting pipe 471, a main pipe 48, a second valve 49, a third valve 410, a first feeding hole 411 and a second feeding hole 412.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

Example 1:

referring to the attached drawings 1-5, the pu's alloy furnace roller batching device provided by the invention comprises a high-temperature reaction kettle 1, wherein pushing structures 2 are fixedly arranged on both sides of the high-temperature reaction kettle 1, a first valve 3 is fixedly arranged at the top end of each pushing structure 2, batching structures 4 are fixedly arranged on both sides of the high-temperature reaction kettle 1, each batching structure 4 comprises a first batching bin 41, a first batching bin 41 is fixedly arranged on one side of the high-temperature reaction kettle 1, a second batching bin 42 is fixedly arranged on one side of the high-temperature reaction kettle 1, which is far away from the first batching bin 41, the bottom ends of the first batching bin 41 and the second batching bin 41 are fixedly connected with the first valve 3, each of the first batching bin 41 and the second batching bin 41 comprises a first isolation bin 43, a second isolation bin 44 is fixedly arranged on one side of the first isolation bin 43, and a third isolation bin 45 is fixedly arranged on one side of the second isolation bin 44, which is far away from the first isolation bin 43, a fourth isolation bin 46 is fixedly installed on one side, far away from the second isolation bin 44, of the third isolation bin 45, a fifth isolation bin 47 is fixedly installed on one side, far away from the third isolation bin 45, of the fourth isolation bin 46, and the size ratio of spaces among the first isolation bin 43, the second isolation bin 44, the third isolation bin 45, the fourth isolation bin 46 and the fifth isolation bin 47 is 1:2:3:4:5, the top ends of the first isolation bin 43, the second isolation bin 44, the third isolation bin 45, the fourth isolation bin 46 and the fifth isolation bin 47 are respectively and fixedly connected with a first connecting pipe 431, a second connecting pipe 441, a third connecting pipe 451, a fourth connecting pipe 461 and a fifth connecting pipe 471, the top ends of the first connecting pipe 431, the second connecting pipe 441, the third connecting pipe 451, the fourth connecting pipe 461 and the fifth connecting pipe 471 are all and fixedly connected with a main pipe 48, the top end of the main pipe 48 on the first batching bin 41 is fixedly provided with a first feeding port 410, and the top end of the main pipe 48 on the second batching bin 42 is fixedly provided with a second feeding port 411;

further, the top end and the bottom end of the first connecting pipe 431, the second connecting pipe 441, the third connecting pipe 451, the fourth connecting pipe 461 and the fifth connecting pipe 471 are fixedly provided with a second valve 49, and the main pipe 48 is fixedly provided with a third valve 410;

further, the material pushing structure 2 comprises a material pushing box 21, a material outlet 211 is formed in one side of the material pushing box 21, the material outlet 211 is fixedly connected with the high-temperature reaction kettle 1, a motor 22 is fixedly installed on one side, far away from the material outlet 211, of the material pushing box 21, and an auger 23 is fixedly connected with the output end of the motor 22 and extends into the material pushing box 21;

further, an arc-shaped isolation plate 11 is fixedly installed in the high-temperature reaction kettle 1, and a mixing structure 12 is arranged above the arc-shaped isolation plate 11;

further, the mixing structure 12 comprises a second motor 121, the second motor 121 is fixedly installed at the top end of the high-temperature reaction kettle 1, the output end of the second motor 121 is fixedly connected with a rotating rod 122, the bottom end of the rotating rod 122 is movably connected with the arc-shaped isolation plate 11, an arc-shaped mixing plate 123 is fixedly installed on the rotating rod 122, and a second discharge hole 124 is formed in the bottom end of the arc-shaped mixing plate 123;

further, a high-temperature fusion bin 13 is arranged below the high-temperature reaction kettle 1;

a puh alloy furnace roller batching method further comprises the following specific steps:

the method comprises the following steps: taking aluminum particles, copper particles, silicon particles, magnesium particles, zinc particles and manganese powder;

step two: the ratio of aluminum particles, copper particles, silicon particles, magnesium particles, zinc particles and manganese powder required for preparing the required alloy is 9: 1: 3: 2: 1: 2;

step three: aluminum particles, copper particles, silicon particles and magnesium particles are sequentially led into a main pipe 48 on a first batching bin 41 through a first feeding port 410, aluminum particles are led into a fourth isolation bin 46 and a fifth isolation bin 47 through a third valve 410 and a first connecting pipe 431, a second connecting pipe 441, a third connecting pipe 451, a fourth connecting pipe 461 and a second valve 49 on a fifth connecting pipe 471 on the control main pipe 48, copper particles are led into a first isolation bin 43 through the first connecting pipe 431, silicon particles are led into a third isolation bin 45 through the third connecting pipe 451, magnesium particles are led into a second isolation bin 44 through the second connecting pipe 441, zinc particles and manganese powder are sequentially led into the main pipe 48 on a second batching bin 42 through a second feeding port 411, the third valve 410 on the control main pipe 48 and the first connecting pipe 431 and the second valve 49 on the second connecting pipe 441, zinc particles are guided into the first isolation bin 43 on the second batching bin 44 through the first connecting pipe 431, and manganese powder is guided into the second isolation bin 44 on the second batching bin 44 through the second connecting pipe 441;

step four: controlling the first valve 3 to pour the materials in the first isolation bin 43, the second isolation bin 44, the third isolation bin 45, the fourth isolation bin 46 and the fifth isolation bin 47 in the first proportioning bin 41 and the materials in the first isolation bin 43 and the second isolation bin 44 in the second proportioning bin 41 into the material pushing box 21;

step five: turning on a motor 22 to drive a packing auger 23 to guide the materials in the material pushing box 21 into the high-temperature reaction kettle 1 through a material outlet 211, and turning on a second motor 121 to drive an arc-shaped isolation plate 11 to mix the materials;

step six: the mixture is led into the high-temperature fusion bin 13 through a second discharge hole 124 and is melted and fused at high temperature;

step seven: and after the fusion is finished, the high-temperature reaction kettle 1 is led out for pouring the pu's alloy furnace roller.

The using process of the invention is as follows: when the invention is used, the arc-shaped isolation plate 11 is fixedly arranged in the high-temperature reaction kettle 1, the second motor 121 is fixedly arranged in the high-temperature reaction kettle 1, the output end of the second motor 121 extends into the high-temperature reaction kettle 1 and is fixedly connected with the rotating rod 122, the arc-shaped plate mixing plate 123 is fixedly connected with the rotating rod 122, the bottom end of the arc-shaped plate mixing plate 123 is provided with the second discharge hole 124, the material pushing box 21 is fixedly arranged at both sides of the high-temperature reaction kettle 1, the motor 22 is fixedly arranged at one side of the material pushing box 21 far away from the high-temperature reaction kettle 1, the output end of the motor 22 extends into the material pushing box 21 and is fixedly connected with the auger 23, the bottom end of the auger 23 is movably connected with the material pushing box 21, the first valve 3 is fixedly arranged at the top end of the material pushing box 21, the first proportioning bin 41 and the second proportioning bin 42 are respectively and fixedly arranged, The bottom ends of the second connecting pipe 441, the third connecting pipe 451, the fourth connecting pipe 461 and the fifth connecting pipe 471 are respectively and fixedly connected with the first isolation bin 43, the second isolation bin 44, the third isolation bin 45, the fourth isolation bin 46 and the fifth isolation bin 47, the top ends of the first connecting pipe 431, the second connecting pipe 441, the third connecting pipe 451, the fourth connecting pipe 461 and the fifth connecting pipe 471 are fixedly connected with a main pipe 48, the top end of the main pipe 48 on the first proportioning bin 41 is fixedly connected with a first feeding port 411, and the top end of the main pipe 48 on the second proportioning bin 42 is fixedly connected with a second feeding port 412.

Example 2:

referring to the attached figure 6, the pu's alloy furnace roller batching device provided by the invention comprises a material pushing structure 2, an electric telescopic rod 24 and a push plate 25, wherein the bottom end of the electric telescopic rod 24 is fixedly connected with one side, far away from a material outlet 211, of a material pushing box 21, the top end of the electric telescopic rod 24 is fixedly connected with the push plate 25, and the push plate 25 is movably connected with the material pushing box 21.

The using process of the invention is as follows: when the high-temperature reaction kettle is used, the arc-shaped isolation plate 11 is fixedly arranged in the high-temperature reaction kettle 1, the second motor 121 is fixedly arranged in the high-temperature reaction kettle 1, the output end of the second motor 121 extends into the high-temperature reaction kettle 1 and is fixedly connected with the rotating rod 122, the arc-shaped plate mixing plate 123 is fixedly connected with the rotating rod 122, the bottom end of the arc-shaped plate mixing plate 123 is provided with a second discharge hole 124, the two sides of the high-temperature reaction kettle 1 are fixedly provided with the material pushing box 21, the electric telescopic rod 24 is fixedly arranged at one side of the material pushing box 21 far away from the high-temperature reaction kettle 1, the top end of the electric telescopic rod 24 is fixedly connected with the push plate 25 in an extending manner, the push plate 25 is movably connected with the material pushing box 21, the first valve 3 is fixedly arranged at the top end of the material pushing box 21, the first proportioning bin 41 and the second proportioning bin 42 are respectively and, The bottom ends of the second connecting pipe 441, the third connecting pipe 451, the fourth connecting pipe 461 and the fifth connecting pipe 471 are respectively and fixedly connected with the first isolation bin 43, the second isolation bin 44, the third isolation bin 45, the fourth isolation bin 46 and the fifth isolation bin 47, the top ends of the first connecting pipe 431, the second connecting pipe 441, the third connecting pipe 451, the fourth connecting pipe 461 and the fifth connecting pipe 471 are fixedly connected with a main pipe 48, the top end of the main pipe 48 on the first proportioning bin 41 is fixedly connected with a first feeding port 411, and the top end of the main pipe 48 on the second proportioning bin 42 is fixedly connected with a second feeding port 412.

The above description is only a preferred embodiment of the present invention, and any person skilled in the art may modify the present invention or modify it into an equivalent technical solution by using the technical solution described above. Therefore, any simple modifications or equivalent substitutions made in accordance with the technical solution of the present invention are within the scope of the claims of the present invention.

Claims (8)

1. The utility model provides a pu's alloy stove roller dosing unit, includes high temperature reaction cauldron (1), its characterized in that: the high-temperature reaction kettle is characterized in that material pushing structures (2) are fixedly mounted on two sides of the high-temperature reaction kettle (1), a first valve (3) is fixedly mounted on the top end of the material pushing structures (2), batching structures (4) are fixedly mounted on two sides of the high-temperature reaction kettle (1), a first batching bin (41) is fixedly mounted on one side of the high-temperature reaction kettle (1), a second batching bin (42) is fixedly mounted on one side, away from the first batching bin (41), of the high-temperature reaction kettle (1), the bottom ends of the first batching bin (41) and the second batching bin (41) are fixedly connected with the first valve (3), the first batching bin (41) and the second batching bin (41) both comprise first isolation bins (43), a second isolation bin (44) is fixedly mounted on one side, away from the first isolation bins (43), and a third isolation bin (45) are fixedly mounted on one side, away from the second isolation bins (44), a fourth isolation bin (46) is fixedly installed on one side, away from the second isolation bin (44), of the third isolation bin (45), a fifth isolation bin (47) is fixedly installed on one side, away from the third isolation bin (45), of the fourth isolation bin (46), and the size ratio of spaces among the first isolation bin (43), the second isolation bin (44), the third isolation bin (45), the fourth isolation bin (46) and the fifth isolation bin (47) is 1:2:3:4:5, the top ends of the first isolation bin (43), the second isolation bin (44), the third isolation bin (45), the fourth isolation bin (46) and the fifth isolation bin (47) are respectively and fixedly connected with a first connecting pipe (431), a second connecting pipe (441), a third connecting pipe (451), a fourth connecting pipe (461) and a fifth connecting pipe (471), the top ends of the first connecting pipe (431), the second connecting pipe (441), the third connecting pipe (451), the fourth connecting pipe (461) and the fifth connecting pipe (471) are respectively and fixedly connected with a main pipe (48), the top end of the main pipe (48) on the first proportioning bin (41) is fixedly provided with a first feeding port (410), and the top end of the main pipe (48) on the second proportioning bin (42) is fixedly provided with a second feeding port (411).

2. The pu's alloy furnace roller batching device according to claim 1, characterized in that: the first connecting pipe (431), the second connecting pipe (441), the third connecting pipe (451), the fourth connecting pipe (461), the fifth connecting pipe (471) are fixedly provided with second valves (49) at the top end and the bottom end, and the main pipe (48) is fixedly provided with third valves (410).

3. The pu's alloy furnace roller batching device according to claim 1, characterized in that: push away material structure (2) including pushing away workbin (21), push away workbin (21) one side and seted up discharge gate (211), discharge gate (211) and high temperature reaction cauldron (1) fixed connection, it has motor (22) to push away workbin (21) and keep away from discharge gate (211) one side fixed mounting, motor (22) output extends to and pushes away workbin (21) interior fixedly connected with auger (23).

4. The pu's alloy furnace roller batching device according to claim 1, characterized in that: an arc-shaped isolation plate (11) is fixedly arranged in the high-temperature reaction kettle (1), and a mixing structure (12) is arranged above the arc-shaped isolation plate (11).

5. The pu's alloy furnace roller batching device according to claim 4, characterized in that: mixing structure (12) include second motor (121), high temperature reaction kettle (1) top fixed mounting has second motor (121), second motor (121) output end fixedly connected with dwang (122), dwang (122) bottom and arc division board (11) swing joint, fixed mounting has arc mixing plate (123) on dwang (122), second discharge gate (124) have been seted up to arc mixing plate (123) bottom.

6. The pu's alloy furnace roller batching device according to claim 1, characterized in that: a high-temperature fusion bin (13) is arranged below the high-temperature reaction kettle (1).

7. The pu's alloy furnace roller batching device according to claim 1, characterized in that: push away material structure (2) and still include electric telescopic handle (24), push pedal (25), discharge gate (211) one side fixed connection is kept away from with push away workbin (21) in electric telescopic handle (24) bottom, electric telescopic handle (24) top fixedly connected with push pedal (25), push pedal (25) with push away workbin (21) swing joint.

8. A pu's alloy furnace roller batching method is characterized in that: the method also comprises the following specific steps:

the method comprises the following steps: taking aluminum particles, copper particles, silicon particles, magnesium particles, zinc particles and manganese powder;

step two: the ratio of aluminum particles, copper particles, silicon particles, magnesium particles, zinc particles and manganese powder required for preparing the required alloy is 9: 1: 3: 2: 1: 2;

step three: aluminum particles, copper particles, silicon particles and magnesium particles are sequentially led into a main pipe (48) on a first proportioning bin (41) through a first feeding port (410), a third valve (410) on the main pipe (48), a first connecting pipe (431), a second connecting pipe (441), a third connecting pipe (451), a fourth connecting pipe (461) and a second valve (49) on a fifth connecting pipe (471) are controlled, the aluminum particles are led into a fourth isolating bin (46) and a fifth isolating bin (47) through the fourth connecting pipe (461) and the fifth connecting pipe (471), the copper particles are led into a first isolating bin (43) through the first connecting pipe (431), the silicon particles are led into a third isolating bin (45) through the third connecting pipe (451), the magnesium particles are led into a second isolating bin (44) through the second connecting pipe (441), and zinc particles and manganese powder are led into the main pipe (48) on the second proportioning bin (42) through a second feeding port (411), controlling a third valve (410) on the main pipe (48), a first connecting pipe (431), a second connecting pipe (441) and a second valve (49) on the second connecting pipe (441), guiding zinc particles into a first isolation bin (43) on a second proportioning bin (44) through the first connecting pipe (431), and guiding manganese powder into a second isolation bin (44) on the second proportioning bin (44) through the second connecting pipe (441);

step four: controlling a first valve (3) to pour materials in a first isolation bin (43), a second isolation bin (44), a third isolation bin (45), a fourth isolation bin (46) and a fifth isolation bin (47) in a first proportioning bin (41) and materials in the first isolation bin (43) and the second isolation bin (44) in the second proportioning bin (41) into a material pushing box (21);

step five: opening a motor (22) to drive a packing auger (23) to guide the materials in the material pushing box (21) into the high-temperature reaction kettle (1) through a discharge port (211), and opening a second motor (121) to drive an arc-shaped isolation plate (11) to mix the materials;

step six: the mixture is led into a high-temperature fusion bin (13) through a second discharge hole (124) and is melted and fused at high temperature;

step seven: and after the fusion is finished, the high-temperature reaction kettle (1) is led out for pouring the pu's alloy furnace roller.

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