CN111530374B - Deoxidizing agent, preparation system and preparation method - Google Patents

Abstract

The invention relates to preparation of a deoxidizer, in particular to a deoxidizer, a preparation system and a preparation method. The preparation process comprises the following steps of putting raw materials into a preparation room for kneading uniformly: adding the kneaded raw materials into an extruder to knead strips to obtain a semi-finished deoxidizer; cutting the strip-shaped semi-finished deoxidizer into particles; drying the granular semi-finished deoxidizer, and heating the deoxidizer without melting the deoxidizer. The raw materials of the deoxidizer are added with a silver nitrate aqueous solution before being uniformly kneaded.

Description

Deoxidizing agent, preparation system and preparation method

Technical Field

The invention relates to preparation of a deoxidizer, in particular to a deoxidizer, a preparation system and a preparation method.

Background

Deoxidizers, also known as oxygen scavengers and oxygen absorbers, are a group of chemical mixtures that readily react with free or dissolved oxygen. The partial deoxidizer is prepared by kneading raw materials, preparing strip materials by an extruder, cutting the strip materials into sections, drying and roasting. The steps taking a long time are generally kneading, drying and roasting, and the drying and roasting time is mostly a fixed value, so in order to increase the preparation efficiency, the kneading time is usually reduced, but the kneading and mixing effect is greatly reduced.

Disclosure of Invention

The invention aims to provide a deoxidizer, a preparation system and a preparation method, which can quickly and fully knead raw materials.

The purpose of the invention is realized by the following technical scheme:

the utility model provides a deoxidier preparation system, including the preparation room, push away and rub mechanism I, the body frame, the power roof-rack, link gear I, link gear II and hold between the fingers the ware, it is provided with four to push away rubs mechanism I, four push away rub the even lower extreme of installing in preparation room of I circumference of mechanism, the body frame rigid coupling is in the upper end in the preparation room, power roof-rack rigid coupling is in the upper end of body frame, link gear I is connected on the body frame, the inner wall sliding connection of link gear I is on the power roof-rack, the downside at link gear I is connected to link gear II, hold between the fingers the downside of ware rigid coupling at link gear II.

The preparation room is including preparing room body, base, discharging pipe, spiral leaf and motor I, four bases of the even rigid coupling of lower extreme circumference of preparation room body, discharging pipe and the middle part rigid coupling and the intercommunication of preparation room body lower extreme, and the spiral leaf sets up in the discharging pipe, and the spiral leaf passes through the drive of motor I, and I rigid couplings of motor are at the lower extreme of preparation room body.

The pushing and kneading mechanism I comprises a dowel plate, a round rod, a pushing and kneading part I and an electric telescopic rod I, wherein the upper side of the inner end of the dowel plate is fixedly connected with the round rod, the inner end of the round rod is fixedly connected with the pushing and kneading part I, and the movable end of the electric telescopic rod I is fixedly connected with the lower side of the inner end of the dowel plate; four round bars all with preparation room body sliding connection, four electric telescopic handle I rigid coupling respectively on four bases, four outer terminal surfaces of pushing away portion I all with the interior terminal surface laminating of preparation room body.

The main frame comprises a main frame body, a key part I, a support rod and an electric telescopic rod II, wherein the main frame body is fixedly connected to the upper end of the preparation chamber body, the key part I is arranged at the middle part of the main frame body, and the electric telescopic rod II is fixedly connected to the main frame body.

The power roof rack comprises a double-layer rack, a motor II and a key groove I, the double-layer rack is fixedly connected to the upper end of the supporting rod, the motor II is fixedly connected to the upper end of the double-layer rack, an output shaft of the motor II is rotatably connected with the double-layer rack, and the key groove I is arranged on the output shaft of the motor II.

Link gear I is including linkage pipe I, keyway II, linkage pipe II, key portion II, connecting portion and universal ball shell, be equipped with keyway II on the outer wall of linkage pipe I, the outer wall of linkage pipe II rotates with the inner wall of linkage pipe I to be connected, be equipped with key portion II on the inner wall of linkage pipe II, the connecting portion rigid coupling is at the upside of linkage pipe I, universal ball shell rigid coupling is at the lower extreme of linkage pipe II, the output shaft sliding connection of motor II is in linkage pipe II, II sliding connection of key portion are in keyway I, the connecting portion rigid coupling is at electric telescopic handle's II expansion end.

The linkage mechanism II comprises a linkage frame, a cross shaft, connecting pipes, a wedge-shaped frame and universal ball balls, the linkage frame is fixedly connected to the lower end of the linkage pipe I, the left end and the right end of the cross shaft are rotatably connected to the left end and the right end of the lower side of the linkage frame respectively, the front end and the rear end of the cross shaft are rotatably connected with one connecting pipe respectively, the front end and the rear end of the lower end of the wedge-shaped frame are fixedly connected to the two connecting pipes respectively, the upper end of the wedge-shaped frame is fixedly connected with the universal ball balls, and the universal ball balls are rotatably connected into a universal ball shell.

The kneading and pushing device comprises a connecting ring, an inlet shaft and a pushing and kneading part II, wherein the lower end of the connecting ring is uniformly and fixedly connected with three inlet shafts in the circumferential direction, the lower ends of the three inlet shafts are respectively and fixedly connected with one pushing and kneading part II, and the connecting ring is fixedly connected with the outer ends of the two connecting pipes.

The method for preparing the deoxidizer by adopting the deoxidizer preparation system comprises the following steps:

step 1: putting the raw materials into a preparation room for kneading uniformly:

step 2: adding the kneaded raw materials into an extruder to knead strips to obtain a semi-finished deoxidizer;

and step 3: cutting the strip-shaped semi-finished deoxidizer into particles;

and 4, step 4: drying the granular semi-finished deoxidizer, and heating the deoxidizer without melting the deoxidizer.

The deoxidizer prepared by the preparation method of the deoxidizer is prepared by adding a silver nitrate aqueous solution into the raw materials of the deoxidizer before uniformly kneading.

The beneficial effects of the deoxidizer preparation system of the invention are as follows:

two pushing and kneading parts I at two mirror symmetry positions are close to each other, so that the raw materials are drawn close to the middle to obtain lateral kneading; the pushing and kneading part II moves downwards to push and knead the raw materials and then part of the raw materials enter the raw materials, when the pushing and kneading part II moves upwards, the bottom of the raw materials can be turned over to the upper part, and the mixing effect is better when the pushing and kneading part II pushes and kneads the raw materials again; the plurality of pushing and kneading parts II move downwards in a connected sequence and also move upwards in a connected sequence, so that the raw materials are not scattered everywhere and keep a relatively aggregated state when being pushed and kneaded, subsequent strip making and section cutting are facilitated, and the raw materials are well formed; the pushing and kneading part II is combined with the pushing and kneading part I, so that the raw materials can be repeatedly pushed, kneaded and kneaded, the mixing speed is high, and the mixing is more sufficient.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic view showing the overall construction of a deoxidizer manufacturing system according to the present invention;

FIG. 2 is a partial schematic view of the first embodiment of the present invention;

FIG. 3 is a second partial schematic structural view of the present invention;

FIG. 4 is a third schematic view of a portion of the present invention;

FIG. 5 is a fourth schematic view of a portion of the present invention;

FIG. 6 is a schematic diagram of a portion of the present invention;

FIG. 7 is a schematic diagram six of a portion of the present invention;

FIG. 8 is a seventh schematic view of a portion of the present invention;

fig. 9 is a partial structural schematic view eight of the present invention.

In the figure: a preparation chamber 1; a preparation chamber body 101; a base 102; a tapping pipe 103; helical blades 104; a motor I105; a pushing and kneading mechanism I2; a force transmission plate 201; a round bar 202; a pushing and kneading part I203; an electric telescopic rod I204; a main frame 3; a main frame body 301; a bond I302; a stay bar 303; an electric telescopic rod II 304; a power top frame 4; a double shelf 401; a motor II 402; a key slot I403; a linkage mechanism I5; a linkage pipe I501; a key groove II 502; a linkage pipe II 503; a key II 504; a connecting portion 505; a gimbaled ball housing 506; a linkage mechanism II 6; a linkage frame 601; a cross-shaft 602; a connection pipe 603; a wedge frame 604; a ball-and-socket ball 605; a kneading and pushing device 7; an attachment ring 701; an input shaft 702; pushing and kneading part II 703.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The first embodiment is as follows:

as shown in fig. 1-9, a deoxidizer preparation system, including preparation room 1, push and rub mechanism I2, body frame 3, power roof-rack 4, link gear I5, link gear II 6 and pinching and pushing ware 7, it is provided with four to push and rub mechanism I2, four push and rub mechanism I2 circumference even lower extreme of installing at preparation room 1, body frame 3 rigid coupling is in the upper end of preparation room 1, power roof-rack 4 rigid coupling is in the upper end of body frame 3, link gear I5 connects on body frame 3, the inner wall sliding connection of link gear I5 is on power roof-rack 4, link gear II 6 connects the downside at link gear I5, pinching and pushing ware 7 rigid coupling is in the downside of link gear II 6.

The second embodiment is as follows:

as shown in fig. 1-9, the preparation chamber 1 includes a preparation chamber body 101, bases 102, a discharge pipe 103, a spiral blade 104 and a motor i 105, four bases 102 are uniformly and fixedly connected to the lower end of the preparation chamber body 101 in the circumferential direction, the discharge pipe 103 is fixedly connected and communicated with the middle portion of the lower end of the preparation chamber body 101, the spiral blade 104 is disposed in the discharge pipe 103, the spiral blade 104 is driven by the motor i 105, and the motor i 105 is fixedly connected to the lower end of the preparation chamber body 101. The raw materials are put into the preparation chamber body 101, and the upper end of the discharge pipe 103 is provided with a valve.

The third concrete implementation mode:

as shown in fig. 1-9, the pushing and kneading mechanism i 2 includes a force transmission plate 201, a round bar 202, a pushing and kneading part i 203, and an electric telescopic rod i 204, wherein the upper side of the inner end of the force transmission plate 201 is fixedly connected with the round bar 202, the inner end of the round bar 202 is fixedly connected with the pushing and kneading part i 203, and the movable end of the electric telescopic rod i 204 is fixedly connected with the lower side of the inner end of the force transmission plate 201; four round bars 202 are all connected with the preparation chamber body 101 in a sliding mode, four electric telescopic rods I204 are fixedly connected to the four bases 102 respectively, and the outer end faces of the four pushing and kneading parts I203 are all attached to the inner end face of the preparation chamber body 101. The electric telescopic rod I204 is used for driving the force transmission plate 201 to move left and right, and the force transmission plate 201 enables the force transmission plate 201 to drive the pushing and kneading part I203 to move left and right. When the raw material in the preparation chamber body 101 is kneaded, first, the two pushing and kneading portions i 203 at mirror symmetry positions are brought close to each other, for example, the two pushing and kneading portions i 203 at the left and right sides are brought close to each other to press the left and right sides of the raw material to the inner side, then the two pushing and kneading portions i 203 at the left and right sides are brought away from each other to bring the two kneading portions i 203 at the front and rear sides close to each other to press the front and rear sides of the raw material to the inner side, and at this time, the raw material is brought closer to the middle to be kneaded in a lateral direction.

The fourth concrete implementation mode:

as shown in fig. 1 to 9, the main frame 3 includes a main frame body 301, a key portion i 302, a stay bar 303, and an electric telescopic rod ii 304, the main frame body 301 is fixedly connected to the upper end of the preparation chamber body 101, the key portion i 302 is disposed in the middle of the main frame body 301, and the electric telescopic rod ii 304 is fixedly connected to the main frame body 301. And the electric telescopic rod II 304 is used for driving the linkage mechanism I5 to integrally lift.

The fifth concrete implementation mode:

as shown in fig. 1-9, the power top frame 4 includes a double-layer frame 401, a motor ii 402 and a key slot i 403, the double-layer frame 401 is fixedly connected to the upper end of the brace 303, the motor ii 402 is fixedly connected to the upper end of the double-layer frame 401, an output shaft of the motor ii 402 is rotatably connected to the double-layer frame 401, and the key slot i 403 is arranged on the output shaft of the motor ii 402. And starting a motor II 402, wherein the motor II 402 is used for driving the linkage pipe II 503 to rotate.

The sixth specific implementation mode:

as shown in fig. 1-9, the linkage mechanism i 5 includes a linkage pipe i 501, a key groove ii 502, a linkage pipe ii 503, a key portion ii 504, a connection portion 505 and a universal ball housing 506, the key groove ii 502 is provided on the outer wall of the linkage pipe i 501, the outer wall of the linkage pipe ii 503 is rotatably connected with the inner wall of the linkage pipe i 501, the key portion ii 504 is provided on the inner wall of the linkage pipe ii 503, the connection portion 505 is fixedly connected on the upper side of the linkage pipe i 501, the universal ball housing 506 is fixedly connected to the lower end of the linkage pipe ii 503, the output shaft of the motor ii 402 is slidably connected in the linkage pipe ii 503, the key portion ii 504 is slidably connected in the key groove i 403, and the connection portion 505 is fixedly connected to the movable end of the electric telescopic rod ii 304. Linkage pipe II 503 rotates in linkage pipe I501, and linkage pipe I501 is connected with electric telescopic handle II 304 through connecting portion 505, so linkage pipe I501 does not rotate.

The seventh embodiment:

as shown in fig. 1-9, the linkage mechanism ii 6 includes a linkage frame 601, a cross 602, connection pipes 603, a wedge frame 604, and ball bearings 605, the linkage frame 601 is fixedly connected to the lower end of the linkage pipe i 501, the left and right ends of the cross 602 are respectively rotatably connected to the left and right ends of the lower side of the linkage frame 601, the front and rear ends of the cross 602 are respectively rotatably connected to one connection pipe 603, the front and rear ends of the lower end of the wedge frame 604 are respectively fixedly connected to the two connection pipes 603, the upper end of the wedge frame 604 is fixedly connected to the ball bearings 605, and the ball bearings 605 are rotatably connected in the ball housing 506. The linkage frame 601 ascends and descends along with the ascending and descending of the linkage pipe I501. Linkage pipe II 503 drives universal ball housing 506 to rotate around the axis of linkage pipe II 503, and universal ball 605 rotates around the axis of linkage pipe II 503 with the rotation of universal ball housing 506. Referring to fig. 8, when ball 605 rotates to the rear side, wedge frame 604 swings backward, and cross shaft 602 tilts backward, and adapter 701 moves downward toward the rear side; when the ball 605 rotates to the right, the wedge frame 604 swings to the right, the cross shaft 602 is horizontal, and the right side of the connecting ring 701 moves downwards; when the ball 605 rotates to the front side, the wedge frame 604 swings forwards, the cross shaft 602 tilts forwards and downwards, and the front side of the connecting ring 701 moves downwards; when ball 605 rotates to the left, wedge 604 swings to the left, cross 602 is horizontal, and the left side of collar 701 moves downward. That is, in which direction the ball-and-socket joint 605 rotates, the adapter 701 moves downward.

The specific implementation mode is eight:

as shown in fig. 1-9, the kneading and pushing device 7 includes a connecting ring 701, an input shaft 702 and a kneading part ii 703, the lower end of the connecting ring 701 is uniformly fixed with three input shafts 702 in the circumferential direction, the lower ends of the three input shafts 702 are respectively fixed with one kneading part ii 703, and the connecting ring 701 is fixed at the outer ends of two connecting pipes 603. The connecting ring 701 can drive any one of the pushing and kneading parts II 703 to repeatedly move up and down, and when the pushing and kneading parts II 703 move downwards, the pushing and kneading parts II move towards the center of the preparation chamber body 101, namely, the raw materials at the center are pushed, kneaded and mixed, the raw materials are changed from being gathered towards the middle through the pushing and kneading part I203 to being diffused towards the periphery through the pushing and kneading parts II 703, and the gathering and the diffusion are repeated, so that the mixing of the pushing and kneading mode is carried out, and the mixing effect of the flexible raw materials is better. The pushing and kneading part II 703 is preferably C-shaped, and moves downwards to push and knead the raw material and then partially enter the raw material, and when moving upwards, the bottom of the raw material can be overturned to the upper part, so that the mixing effect is better when pushing and kneading again. The plurality of pushing and kneading parts II 703 move downwards in sequence and also move upwards in sequence, so that the raw materials are not scattered everywhere and keep a relatively aggregated state when being pushed and kneaded, the subsequent strip making and section cutting are facilitated, and the raw materials are well formed. The larger the number of the pushing-kneading sections II 703 is, the more finely the points where the raw material is pushed and kneaded increase, and the more thoroughly the raw material can be repeatedly pushed and kneaded by using the pushing-kneading sections I203, so that the mixing speed is high and the mixing is more sufficient.

The specific implementation method nine:

as shown in fig. 1 to 9, a method for preparing a deoxidizer using the deoxidizer preparation system includes the steps of:

step 1: the raw materials are put into the preparation chamber 1 for kneading uniformly:

step 2: adding the kneaded raw materials into an extruder to knead strips to obtain a semi-finished deoxidizer;

and step 3: cutting the strip-shaped semi-finished deoxidizer into particles;

and 4, step 4: drying the granular semi-finished deoxidizer, and heating the deoxidizer without melting the deoxidizer.

The deoxidizer prepared by the preparation method is characterized in that the raw material of the deoxidizer is added with a silver nitrate aqueous solution before the raw material is uniformly kneaded.

The invention relates to a deoxidizer preparation system, which has the working principle that:

the raw materials are put into the preparation chamber body 101, and the upper end of the discharge pipe 103 is provided with a valve. The electric telescopic rod I204 is used for driving the force transmission plate 201 to move left and right, and the force transmission plate 201 enables the force transmission plate 201 to drive the pushing and kneading part I203 to move left and right. When the raw material in the preparation chamber body 101 is kneaded, first, the two pushing and kneading portions i 203 at mirror symmetry positions are brought close to each other, for example, the two pushing and kneading portions i 203 at the left and right sides are brought close to each other to press the left and right sides of the raw material to the inner side, then the two pushing and kneading portions i 203 at the left and right sides are brought away from each other to bring the two kneading portions i 203 at the front and rear sides close to each other to press the front and rear sides of the raw material to the inner side, and at this time, the raw material is brought closer to the middle to be kneaded in a lateral direction. And the electric telescopic rod II 304 is used for driving the linkage mechanism I5 to integrally lift. And starting a motor II 402, wherein the motor II 402 is used for driving the linkage pipe II 503 to rotate. Linkage pipe II 503 rotates in linkage pipe I501, and linkage pipe I501 is connected with electric telescopic handle II 304 through connecting portion 505, so linkage pipe I501 does not rotate. The linkage frame 601 ascends and descends along with the ascending and descending of the linkage pipe I501. Linkage pipe II 503 drives universal ball housing 506 to rotate around the axis of linkage pipe II 503, and universal ball 605 rotates around the axis of linkage pipe II 503 with the rotation of universal ball housing 506. Referring to fig. 8, when ball 605 rotates to the rear side, wedge frame 604 swings backward, and cross shaft 602 tilts backward, and adapter 701 moves downward toward the rear side; when the ball 605 rotates to the right, the wedge frame 604 swings to the right, the cross shaft 602 is horizontal, and the right side of the connecting ring 701 moves downwards; when the ball 605 rotates to the front side, the wedge frame 604 swings forwards, the cross shaft 602 tilts forwards and downwards, and the front side of the connecting ring 701 moves downwards; when ball 605 rotates to the left, wedge 604 swings to the left, cross 602 is horizontal, and the left side of collar 701 moves downward. That is, in which direction the ball-and-socket joint 605 rotates, the adapter 701 moves downward. The connecting ring 701 can drive any one of the pushing and kneading parts II 703 to repeatedly move up and down, and when the pushing and kneading parts II 703 move downwards, the pushing and kneading parts II move towards the center of the preparation chamber body 101, namely, the raw materials at the center are pushed, kneaded and mixed, the raw materials are changed from being gathered towards the middle through the pushing and kneading part I203 to being diffused towards the periphery through the pushing and kneading parts II 703, and the gathering and the diffusion are repeated, so that the mixing of the pushing and kneading mode is carried out, and the mixing effect of the flexible raw materials is better. The pushing and kneading part II 703 is preferably C-shaped, and moves downwards to push and knead the raw material and then partially enter the raw material, and when moving upwards, the bottom of the raw material can be overturned to the upper part, so that the mixing effect is better when pushing and kneading again. The plurality of pushing and kneading parts II 703 move downwards in sequence and also move upwards in sequence, so that the raw materials are not scattered everywhere and keep a relatively aggregated state when being pushed and kneaded, the subsequent strip making and section cutting are facilitated, and the raw materials are well formed. The larger the number of the pushing-kneading sections II 703 is, the more finely the points where the raw material is pushed and kneaded increase, and the more thoroughly the raw material can be repeatedly pushed and kneaded by using the pushing-kneading sections I203, so that the mixing speed is high and the mixing is more sufficient.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (4)

1. The utility model provides a deoxidier preparation system, includes preparation room (1), pushes away and rubs mechanism I (2), body frame (3), power roof-rack (4), link gear I (5), link gear II (6) and hold between the fingers and push away ware (7), its characterized in that: four pushing and kneading mechanisms I (2) are arranged, the four pushing and kneading mechanisms I (2) are uniformly arranged at the lower end of the preparation chamber (1) in the circumferential direction, the main frame (3) is fixedly connected at the upper end of the preparation chamber (1), the power top frame (4) is fixedly connected at the upper end of the main frame (3), the linkage mechanism I (5) is connected on the main frame (3), the inner wall of the linkage mechanism I (5) is slidably connected on the power top frame (4), the linkage mechanism II (6) is connected at the lower side of the linkage mechanism I (5), and the kneading and kneading device (7) is fixedly connected at the lower side of the linkage mechanism II (6);

the preparation chamber (1) comprises a preparation chamber body (101), bases (102), a discharge pipe (103), spiral blades (104) and a motor I (105), wherein the four bases (102) are uniformly and fixedly connected to the lower end of the preparation chamber body (101) in the circumferential direction, the discharge pipe (103) is fixedly connected and communicated with the middle of the lower end of the preparation chamber body (101), the spiral blades (104) are arranged in the discharge pipe (103), the spiral blades (104) are driven by the motor I (105), and the motor I (105) is fixedly connected to the lower end of the preparation chamber body (101);

the main frame (3) comprises a main frame body (301), a key part I (302), a support rod (303) and an electric telescopic rod II (304), the main frame body (301) is fixedly connected to the upper end of the preparation chamber body (101), the key part I (302) is arranged in the middle of the main frame body (301), and the electric telescopic rod II (304) is fixedly connected to the main frame body (301);

the power top frame (4) comprises a double-layer frame (401), a motor II (402) and a key slot I (403), the double-layer frame (401) is fixedly connected to the upper end of the stay bar (303), the motor II (402) is fixedly connected to the upper end of the double-layer frame (401), an output shaft of the motor II (402) is rotatably connected with the double-layer frame (401), and the key slot I (403) is arranged on the output shaft of the motor II (402);

the linkage mechanism I (5) comprises a linkage pipe I (501), a key groove II (502), a linkage pipe II (503), a key part II (504), a connecting part (505) and a universal ball shell (506), wherein the key groove II (502) is formed in the outer wall of the linkage pipe I (501), the outer wall of the linkage pipe II (503) is rotatably connected with the inner wall of the linkage pipe I (501), the key part II (504) is formed in the inner wall of the linkage pipe II (503), the connecting part (505) is fixedly connected to the upper side of the linkage pipe I (501), the universal ball shell (506) is fixedly connected to the lower end of the linkage pipe II (503), an output shaft of a motor II (402) is slidably connected into the linkage pipe II (503), the key part II (504) is slidably connected into the key groove I (403), and the connecting part (505) is fixedly connected to the movable end of the electric telescopic rod II (304);

the linkage mechanism II (6) comprises a linkage frame (601), a cross shaft (602), connecting pipes (603), a wedge-shaped frame (604) and universal ball balls (605), the linkage frame (601) is fixedly connected to the lower end of the linkage pipe I (501), the left end and the right end of the cross shaft (602) are respectively and rotatably connected to the left end and the right end of the lower side of the linkage frame (601), the front end and the rear end of the cross shaft (602) are respectively and rotatably connected with one connecting pipe (603), the front end and the rear end of the lower end of the wedge-shaped frame (604) are respectively and fixedly connected to the two connecting pipes (603), the upper end of the wedge-shaped frame (604) is fixedly connected with the universal ball balls (605), and the universal ball balls (605) are rotatably connected into a universal ball shell (506).

2. The deoxidizer preparation system of claim 1, wherein: the pushing and kneading mechanism I (2) comprises a force transfer plate (201), a round rod (202), a pushing and kneading part I (203) and an electric telescopic rod I (204), wherein the upper side of the inner end of the force transfer plate (201) is fixedly connected with the round rod (202), the inner end of the round rod (202) is fixedly connected with the pushing and kneading part I (203), and the movable end of the electric telescopic rod I (204) is fixedly connected with the lower side of the inner end of the force transfer plate (201); the four round rods (202) are all in sliding connection with the preparation chamber body (101), the four electric telescopic rods I (204) are fixedly connected to the four bases (102) respectively, and the outer end faces of the four pushing and kneading parts I (203) are attached to the inner end face of the preparation chamber body (101).

3. The deoxidizer preparation system of claim 2, wherein: the kneading and pushing device (7) comprises a connecting ring (701), an inlet shaft (702) and a pushing and kneading part II (703), wherein the lower end of the connecting ring (701) is uniformly and fixedly connected with three inlet shafts (702) in the circumferential direction, the lower ends of the three inlet shafts (702) are respectively and fixedly connected with one pushing and kneading part II (703), and the connecting ring (701) is fixedly connected with the outer ends of the two connecting pipes (603).

4. The method for preparing a deoxidizer using the deoxidizer preparation system of claim 3, comprising the steps of:

step 1: the raw materials are put into a preparation chamber (1) to be uniformly kneaded:

step 2: adding the kneaded raw materials into an extruder to knead strips to obtain a semi-finished deoxidizer;

and step 3: cutting the strip-shaped semi-finished deoxidizer into particles;

and 4, step 4: drying the granular semi-finished deoxidizer, and heating the deoxidizer without melting the deoxidizer.

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