CN112919835A - Building cement and processing method thereof - Google Patents

Abstract

The invention relates to building cement processing, in particular to building cement and a processing method thereof, and the building cement and the processing method thereof comprise the following steps: the method comprises the following steps: the switching mechanism drives the plurality of processing mechanisms to move, and when the processing mechanisms move to the two sides of the device bracket, the processing mechanisms are limited by the device bracket to move so that the processing mechanisms sequentially pass through the plurality of feeding mechanisms; step two: different cement processing raw materials are sequentially placed in the plurality of feeding mechanisms, and the plurality of feeding mechanisms feed various raw materials into the processing mechanisms according to a proportion; step three: the conversion mechanism drives the processing mechanism to pass through the heating mechanism, and the heating mechanism carries out heating treatment on various raw materials in the processing mechanism; the building cement comprises the following components in parts by weight: 67-70 parts of limestone; 10-15 parts of clay; 0.5 to 1 part of iron ore; 9 to 11 portions of coal. Can quickly process and treat the raw materials of the building cement.

Description

Building cement and processing method thereof

Technical Field

The invention relates to building cement processing, in particular to building cement and a processing method thereof.

Background

For example, publication No. CN112248238A is a new type of construction cement processing equipment. The novel building cement processing equipment has high working efficiency and can fully stir cement and sand. The novel building cement processing equipment comprises a bottom plate and a first support frame, wherein the first support frame is arranged on one side of the top of the bottom plate; the first servo motor is arranged on one side of the top of the first support frame; the feeding mechanism is arranged between one side of the top of the bottom plate and the output shaft of the first servo motor; and a stone breaking mechanism is arranged between the upper part of the first support frame and the output shaft of the first servo motor. Through the matching of the feeding mechanism, the stone breaking mechanism, the filtering mechanism, the material pouring mechanism and the stirring mechanism; the invention has the disadvantage that the raw materials of the building cement cannot be processed quickly.

Disclosure of Invention

The invention aims to provide a method for processing building cement, which can quickly process and treat raw materials of the building cement.

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

a building cement and a processing method thereof, wherein the method comprises the following steps:

the method comprises the following steps: the switching mechanism drives the plurality of processing mechanisms to move, and when the processing mechanisms move to the two sides of the device bracket, the processing mechanisms are limited by the device bracket to move so that the processing mechanisms sequentially pass through the plurality of feeding mechanisms;

step two: different cement processing raw materials are sequentially placed in the plurality of feeding mechanisms, and the plurality of feeding mechanisms feed various raw materials into the processing mechanisms according to a proportion;

step three: the conversion mechanism drives the processing mechanism to pass through the heating mechanism, and the heating mechanism carries out heating treatment on various raw materials in the processing mechanism;

the building cement processing method further relates to a building cement processing device, the building cement processing device comprises a device support, a conversion mechanism, a processing mechanism, a feeding mechanism and a heating mechanism, the device support is connected with the conversion mechanism, the conversion mechanism is connected with the two processing mechanisms in a rotating mode, equal fixedly connected with torsional springs are arranged between the two processing mechanisms and the conversion mechanism, the feeding mechanism is provided with a plurality of feeding mechanisms, the equal fixedly connected feeding mechanisms are connected to one side of the device support, the other side of the device support is connected with the heating mechanism in a sliding mode, and a compression spring I is fixedly connected between the heating mechanism and the device support.

According to the technical scheme, the device support comprises an installation frame, a sliding support, friction strips and an installation support, the sliding support is fixedly connected to the right side of the installation frame, the friction strips are fixedly connected to the left side and the right side of the installation frame, and the installation support is fixedly connected to the installation frame.

As the technical scheme is further optimized, the building cement processing method comprises the following steps that the conversion mechanism comprises a conversion motor, a conversion shaft, sliding cylinders I and sliding columns I, the conversion motor is fixedly connected to an installation frame, the conversion shaft is rotatably connected to the installation frame, the conversion shaft is in transmission connection with output shafts of the conversion motor, the conversion shaft is fixedly connected with the two sliding cylinders I, the two sliding cylinders I are both in sliding connection with the sliding columns I, and compression springs II are fixedly connected between the sliding cylinders I and the sliding cylinders I.

According to the technical scheme, the processing mechanism comprises a material returning conical pulley, a mounting ring, a processing barrel, a processing shaft, stirring blades and a friction wheel, the mounting ring is fixedly connected to the material returning conical pulley, the processing barrel is fixedly connected to the mounting ring, the processing barrel is rotatably connected to the processing barrel, the stirring blades are fixedly connected to the processing shaft, the friction wheel is fixedly connected to the lower end of the processing shaft, the material returning conical pulleys are rotatably connected to the two sliding columns I, and torsion springs are fixedly connected between the material returning conical pulleys and the sliding columns I.

As a further optimization of the technical scheme, the building cement processing device further comprises a pushing mechanism, the pushing mechanism comprises two sliding cylinders II, two sliding columns II, a pushing column and a pulling column, the two sliding cylinders II are connected with the sliding columns II in a sliding mode, a compression spring III is fixedly connected between the sliding columns II and the sliding cylinders II, the two sliding columns II are fixedly connected with the pushing column and the pulling column, and the two sliding cylinders II are fixedly connected with a conversion shaft.

As further optimization of the technical scheme, the building cement processing device further comprises an extrusion mechanism I and a sensor I, wherein the extrusion mechanism I comprises an extrusion frame I and a ship-shaped plate I, locking screw I and extrusion column I, sliding connection has two ship template I on the extrusion frame I, there are two locking screw I through threaded connection on the extrusion frame I, the inboard of two locking screw I pushes up respectively on two ship template I, fixedly connected with extrusion column I on the extrusion frame I, extrusion mechanism I and sensor I all are provided with a plurality ofly, the equal sliding connection in the left side of installation frame of a plurality of extrusion columns I, the equal fixed connection in the left side of installation frame of a plurality of sensors I, equal fixedly connected with compression spring IV between a plurality of extrusion columns I and the installation frame, a plurality of sensors I are located the outside of a plurality of extrusion columns I respectively.

According to the building cement processing method, as the technical scheme is further optimized, the feeding mechanism comprises a feeding box, a feeding pipeline, a telescopic mechanism I and a feeding baffle, the feeding pipeline is fixedly connected to the lower end of the feeding box, the telescopic mechanism I is fixedly connected to the feeding box, the feeding baffle is fixedly connected to the telescopic end of the telescopic mechanism I, the feeding baffle is connected to the feeding box in a sliding mode, the feeding boxes are fixedly connected to the mounting support, and the telescopic mechanisms I are respectively connected with the sensors I.

According to the further optimization of the technical scheme, the building cement processing method comprises the following steps that the heating mechanism comprises a heating sliding block, a heating sliding column, a heating support, a telescopic mechanism II and a heating cavity, the heating sliding block is connected to the sliding support in a sliding mode, the heating sliding column is fixedly connected to the heating sliding block, the heating support is fixedly connected to the heating sliding block, the telescopic mechanism II is fixedly connected to the heating support, the heating cavity is fixedly connected to the telescopic end of the telescopic mechanism II, and a compression spring I is fixedly connected between the heating sliding block and the sliding support.

As a further optimization of the technical scheme, the building cement processing method comprises the steps that the building cement processing device further comprises an extrusion mechanism II, a sensor II and a material returning mechanism, the extrusion mechanism II comprises an extrusion frame II, an extrusion column II, a ship-shaped plate II and locking screws II, the extrusion frame II is fixedly connected with the extrusion column II, the extrusion frame II is slidably connected with two ship-shaped plates II, the extrusion frame II is connected with the two locking screws II through threads, the inner sides of the two locking screws II are respectively propped against the two ship-shaped plates II, the extrusion column II is slidably connected onto a sliding support, a compression spring V is fixedly connected between the extrusion column II and the sliding support, the sensor II is fixedly connected onto the sliding support, the sensor II is positioned on the outer side of the extrusion column II and connected with a telescopic mechanism II, the material returning mechanism comprises a telescopic mechanism III, a material returning rod and a material returning arc plate, fixedly connected with material returned pole on telescopic machanism III's the flexible end, fixedly connected with material returned arc board on the material returned pole, telescopic machanism III fixed connection is on the installing support.

The building cement comprises the following components in parts by weight: 67-70 parts of limestone; 10-15 parts of clay; 0.5 to 1 part of iron ore; 9 to 11 portions of coal.

According to the building cement and the processing method thereof, the plurality of processing mechanisms can be driven to move through the conversion mechanism, and when the processing mechanisms move to the two sides of the device bracket, the processing mechanisms are limited by the device bracket to move, so that the processing mechanisms sequentially pass through the plurality of feeding mechanisms; meanwhile, the pushing mechanism pushes the plurality of extruding mechanisms I to move, the extruding mechanisms I extrude the corresponding sensors I, the sensors I control the corresponding feeding mechanisms to be closed, different cement processing raw materials are sequentially placed in the plurality of feeding mechanisms, and the plurality of feeding mechanisms put a plurality of raw materials into the processing mechanisms in proportion; the conversion mechanism drives the processing mechanism to pass through the heating mechanism and drives the heating mechanism to move, meanwhile, the pushing mechanism pushes the sensor II, the sensor II enables the heating mechanism to be buckled on the processing mechanism, and the heating mechanism carries out heating treatment on various raw materials in the processing mechanism.

Drawings

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

FIG. 1 is a schematic view of the overall construction of a construction cement processing apparatus according to the present invention;

FIG. 2 is a schematic view of the overall construction of the construction cement processing apparatus of the present invention;

FIG. 3 is a schematic view of the conversion mechanism of the present invention;

FIG. 4 is a schematic view of the processing mechanism of the present invention;

FIG. 5 is a schematic view of the pushing mechanism of the present invention;

FIG. 6 is a schematic structural diagram of an extrusion mechanism I of the present invention;

FIG. 7 is a schematic view of the feed mechanism of the present invention;

FIG. 8 is a schematic view of the heating mechanism of the present invention;

FIG. 9 is a schematic structural diagram of a pressing mechanism II of the present invention;

fig. 10 is a schematic structural diagram of the material returning mechanism of the present invention.

In the figure: a device holder 1; a mounting frame 101; a sliding bracket 102; a rubbing strip 103; a mounting bracket 104; a conversion mechanism 2; a switching motor 201; a conversion shaft 202; a sliding cylinder I203; a sliding column I204; a processing mechanism 3; a material returning cone pulley 301; a mounting ring 302; a processing drum 303; a machining shaft 304; the stirring blade 305; a friction wheel 306; a pushing mechanism 4; a sliding cylinder II 401; a sliding column II 402; a push post 403; pulling the post 404; an extrusion mechanism I5; a pressing frame I501; a ship-shaped plate I502; a locking screw I503; an extrusion column I504; a feeding mechanism 6; a supply tank 601; a supply conduit 602; a telescoping mechanism I603; a feed baffle 604; a heating mechanism 7; a heating slider 701; the heating spool 702; heating the support 703; a telescoping mechanism II 704; heating chamber 705; an extrusion mechanism II 8; a pressing frame II 801; an extrusion column II 802; a boat-shaped plate II 803; a locking screw II 804; a sensor I9; a sensor II 10; a material returning mechanism 11; a telescoping mechanism III 1101; a material return rod 1102; and a material returning arc plate 1103.

Detailed Description

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

In the description of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "top", "bottom", "inner", "outer" and "upright", etc., indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed and operated in a specific 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 "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, directly or indirectly connected through an intermediate medium, and may be a communication between two members. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In addition, in the description of the present invention, the meaning of "a plurality", and "a plurality" is two or more unless otherwise specified.

The first embodiment is as follows:

the present embodiment will be described below with reference to fig. 1 to 10, a method for processing construction cement, the method comprising the steps of:

the method comprises the following steps: the conversion mechanism 2 drives the plurality of processing mechanisms 3 to move, and when the processing mechanisms 3 move to the two sides of the device bracket 1, the processing mechanisms 3 are limited by the device bracket 1 to move so that the processing mechanisms 3 sequentially pass through the plurality of feeding mechanisms 6;

step two: different cement processing raw materials are sequentially placed in the plurality of feeding mechanisms 6, and the plurality of feeding mechanisms 6 are used for feeding a plurality of raw materials into the processing mechanism 3 according to a proportion;

step three: the conversion mechanism 2 drives the processing mechanism 3 to pass through the heating mechanism 7, and the heating mechanism 7 carries out heating treatment on various raw materials in the processing mechanism 3;

the building cement processing method further relates to a building cement processing device, the building cement processing device comprises a device support 1, a conversion mechanism 2, a processing mechanism 3, a feeding mechanism 6 and a heating mechanism 7, the conversion mechanism 2 is connected to the device support 1, the conversion mechanism 2 is connected with the two processing mechanisms 3 in a rotating mode, torsion springs are fixedly connected between the two processing mechanisms 3 and the conversion mechanism 2, the feeding mechanism 6 is provided with a plurality of parts, the feeding mechanisms 6 are fixedly connected to one side of the device support 1, the heating mechanism 7 is connected to the other side of the device support 1 in a sliding mode, and a compression spring I is fixedly connected between the heating mechanism 7 and the device support 1.

The second embodiment is as follows:

the present embodiment is described below with reference to fig. 1 to 10, and the present embodiment further describes the first embodiment, where the apparatus bracket 1 includes a mounting frame 101, a sliding bracket 102, a friction strip 103, and a mounting bracket 104, the sliding bracket 102 is fixedly connected to the right side of the mounting frame 101, the friction strip 103 is fixedly connected to both the left and right sides of the mounting frame 101, and the mounting bracket 104 is fixedly connected to the mounting frame 101.

The third concrete implementation mode:

the present embodiment is described below with reference to fig. 1 to 10, and the present embodiment further describes an embodiment two, where the conversion mechanism 2 includes a conversion motor 201, a conversion shaft 202, a sliding cylinder i 203 and a sliding cylinder i 204, the conversion motor 201 is fixedly connected to the mounting frame 101, the conversion shaft 202 is rotatably connected to the mounting frame 101, the conversion shaft 202 is in transmission connection with an output shaft of the conversion motor 201, two sliding cylinders i 203 are fixedly connected to the conversion shaft 202, the sliding cylinders i 204 are both slidably connected to the two sliding cylinders i 203, and a compression spring ii is fixedly connected between the sliding cylinder i 204 and the sliding cylinder i 203; when the device is used, the conversion motor 201 is started, the output shaft of the conversion motor 201 starts to rotate, the output shaft of the conversion motor 201 drives the conversion shaft 202 to rotate, the conversion shaft 202 drives the sliding cylinder I203 to rotate, the sliding cylinder I203 drives the sliding column I204 to rotate, the sliding column I204 drives the processing mechanism 3 to rotate, as shown in fig. 1, the device is in an initial state, when the sliding column I204 drives the processing mechanism 3 to move to the left side of the installation frame 101, as the two sides of the installation frame 101 are smaller than the distance between the two processing mechanisms 3, and the installation frame 101 extrudes the movement of the processing mechanism 3, and in the process that the processing mechanism 3 moves through the installation frame 101, the processing mechanism 3 linearly moves under the limit of the installation frame 101, as shown in fig. 1.

The fourth concrete implementation mode:

the following describes this embodiment with reference to fig. 1 to 10, and this embodiment further describes the third embodiment, the processing mechanism 3 includes a material returning cone pulley 301, a mounting ring 302, a processing barrel 303, a processing shaft 304, a stirring blade 305 and a friction wheel 306, the material returning cone pulley 301 is fixedly connected with the mounting ring 302, the mounting ring 302 is fixedly connected with the processing barrel 303, the processing barrel 303 is rotatably connected with the processing shaft 304, the processing shaft 304 is fixedly connected with a plurality of stirring blades 305, the lower end of the processing shaft 304 is fixedly connected with the friction wheel 306, the two sliding columns i 204 are all rotatably connected with the material returning cone pulley 301, and a torsion spring is fixedly connected between the material returning cone pulley 301 and the sliding columns i 204.

The fifth concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 10, and the present embodiment further describes the fourth embodiment, the building cement processing apparatus further includes a pushing mechanism 4, the pushing mechanism 4 includes two sliding cylinders ii 401, two sliding cylinders ii 402, two pushing columns 403 and two pulling columns 404, the two sliding cylinders ii 401 are all slidably connected to the two sliding cylinders ii 401, a compression spring iii is fixedly connected between the two sliding cylinders ii 402 and the sliding cylinder ii 401, the two sliding cylinders ii 402 are all fixedly connected to the pushing columns 403 and the pulling columns 404, and the two sliding cylinders ii 401 are all fixedly connected to the conversion shaft 202.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1 to 10, and further described with reference to the fifth embodiment, the construction cement processing apparatus further includes an extrusion mechanism i 5 and a sensor i 9, the extrusion mechanism i 5 includes an extrusion frame i 501, a ship-shaped plate i 502, locking screws i 503 and extrusion columns i 504, two ship-shaped plates i 502 are slidably connected to the extrusion frame i 501, two locking screws i 503 are connected to the extrusion frame i 501 through threads, the inner sides of the two locking screws i 503 are respectively supported on the two ship-shaped plates i 502, the extrusion columns i 504 are fixedly connected to the extrusion frame i 501, the extrusion mechanism i 5 and the sensor i 9 are both provided with a plurality of extrusion columns i 504, the extrusion columns i 504 are slidably connected to the left side of the installation frame 101, the sensors i 9 are both fixedly connected to the left side of the installation frame 101, and compression springs are both fixedly connected between the extrusion columns i 504 and the installation frame 101, the plurality of sensors i 9 are located outside the plurality of squeeze columns i 504, respectively.

The seventh embodiment:

the present embodiment is described below with reference to fig. 1 to 10, and the present embodiment further describes an embodiment six, where the feeding mechanism 6 includes a feeding tank 601, a feeding pipeline 602, an expansion mechanism i 603, and a feeding baffle 604, the feeding pipeline 602 is fixedly connected to the lower end of the feeding tank 601, the expansion mechanism i 603 is fixedly connected to the feeding tank 601, the expansion end of the expansion mechanism i 603 is fixedly connected to the feeding baffle 604, the feeding baffle 604 is slidably connected to the feeding tank 601, a plurality of feeding tanks 601 are fixedly connected to the mounting bracket 104, and the expansion mechanisms i 603 are respectively connected to a plurality of sensors i 9.

The specific implementation mode is eight:

the present embodiment is described below with reference to fig. 1 to 10, and the seventh embodiment is further described in the present embodiment, where the heating mechanism 7 includes a heating slider 701, a heating spool 702, a heating support 703, a telescopic mechanism ii 704 and a heating cavity 705, the heating slider 701 is slidably connected to the sliding support 102, the heating spool 702 is fixedly connected to the heating slider 701, the heating support 703 is fixedly connected to the heating slider 701, the telescopic mechanism ii 704 is fixedly connected to the heating support 703, the telescopic end of the telescopic mechanism ii 704 is fixedly connected to the heating cavity 705, and a compression spring i is fixedly connected between the heating slider 701 and the sliding support 102.

The specific implementation method nine:

the embodiment is described below with reference to fig. 1 to 10, and the embodiment further describes an eighth embodiment, the construction cement processing apparatus further includes an extruding mechanism ii 8, a sensor ii 10, and a material returning mechanism 11, the extruding mechanism ii 8 includes an extruding frame ii 801, an extruding column ii 802, a ship-shaped plate ii 803, and a locking screw ii 804, the extruding frame ii 801 is fixedly connected with the extruding column ii 802, the extruding frame ii 801 is slidably connected with two ship-shaped plates ii 803, the extruding frame ii 801 is connected with two locking screws ii 804 through threads, inner sides of the two locking screws ii 804 respectively abut against the two ship-shaped plates ii 803, the extruding column ii 802 is slidably connected to the sliding support 102, a compression spring v is fixedly connected between the extruding column ii 802 and the sliding support 102, the sensor ii 10 is fixedly connected to the sliding support 102, the sensor ii 10 is located outside the extruding column ii 802, sensor II 10 and II 704 of telescopic machanism are connected, and material returned mechanism 11 includes telescopic machanism III 1101, material returned pole 1102 and material returned arc board 1103, and fixedly connected with material returned pole 1102 is served in telescopic machanism III 1101's the flexible, and fixedly connected with material returned arc board 1103 on the material returned pole 1102, and telescopic machanism III 1101 fixed connection is on installing support 104.

The building cement comprises the following components in parts by weight: 67-70 parts of limestone; 10-15 parts of clay; 0.5 to 1 part of iron ore; 9 to 11 portions of coal.

The working principle of the building cement and the processing method thereof is as follows:

when the device is used, the conversion motor 201 is started, the output shaft of the conversion motor 201 starts to rotate, the output shaft of the conversion motor 201 drives the conversion shaft 202 to rotate, the conversion shaft 202 drives the sliding cylinder I203 to rotate, the sliding cylinder I203 drives the sliding column I204 to rotate, and the sliding column I204 drives the processing mechanism 3 to rotate, as shown in fig. 1, the device is in an initial state, when the sliding column I204 drives the processing mechanism 3 to move to the left side of the installation frame 101, as the two sides of the installation frame 101 are smaller than the distance between the two processing mechanisms 3, the installation frame 101 extrudes the movement of the processing mechanism 3, and in the process that the processing mechanism 3 moves through the installation frame 101, the processing mechanism 3 linearly moves under the limit of the installation frame 101, as shown in fig. 1; the friction wheel 306 is in contact with the friction strip 103, the friction strip 103 pushes the friction wheel 306 to rotate, the friction wheel 306 drives the processing shaft 304 to rotate, the processing shaft 304 drives the stirring blades 305 on the processing shaft to rotate, as shown in fig. 1, the sliding cylinder II 401 and the sliding cylinder I203 are located at the same position, while the sliding cylinder I203 rotates, the sliding cylinder II 401 is driven by the conversion shaft 202 to rotate, the sliding cylinder II 401 drives the sliding column II 402 to rotate, the sliding column II 402 drives the pushing column 403 and the pulling column 404 to rotate, the pushing column 403 sequentially passes through the plurality of extrusion mechanisms I5, the length of the two ship-shaped plates I502 on each extrusion frame I501 is adjusted in advance according to use requirements, the sliding positions of the two ship-shaped plates I502 on the extrusion frame I501 can be adjusted in advance, the positions of the two ship-shaped plates I502 are fixed through the locking screws I503, so that the time when the pushing column 403 passes through the two ship-shaped plates I502 is, the length that two ship type boards I502 splice together, promote the post 403 can contact with two ship type boards I502, and then control and promote the time that post 403 passes through two ship type boards I502, and then control the time that corresponding sensor I9 receives the extrusion, sensor I9 and sensor II 10 can be pressure sensor or extrusion sensor, sensor I9 is connected with telescopic machanism I603 through the electric control means that this field is conventional, when sensor I9 receives the extrusion, telescopic machanism I603 withdraws, telescopic machanism I603 drives feed baffle 604 and moves, respectively place different raw materials in a plurality of feed tanks 601 in advance, when processing section of thick bamboo 303 passes through feed tank 601, promote post extrusion mechanism I5, extrusion mechanism I5 extrudees sensor I9, sensor I9 controls the closure of feed tank 601, and then make the raw materials in the feed tank 601 fall in the processing section of thick bamboo 303 that passes through, the processing cylinder 303 sequentially passes through the plurality of feeding boxes 601 to complete the addition of the raw materials, the extrusion time of the sensor I9 is adjusted, the feeding amount of each raw material is further controlled, different use requirements are met, and the plurality of stirring blades 305 rotate and stir during feeding, so that the added raw materials are uniformly mixed; after the processing mechanism 3 receives different raw materials, the processing mechanism 3 moves to the right side of the installation frame 101, meanwhile, the corresponding pushing column 403 and pulling column 404 move to the right side of the installation frame 101, the pulling column 404 is in contact with the heating slider 701 and pushes the heating slider 701 to move forwards, the heating slider 701 drives the telescopic mechanism II 704 and the heating cavity 705 to move forwards, the heating cavity 705 is positioned at the upper side of the processing barrel 303 to move synchronously, the pushing column 403 is in contact with the two ship-shaped plates II 803, the distance between the two ship-shaped plates II 803 is adjusted according to the use requirement in advance, the length of the spliced ship-shaped plates is locked and positioned through the locking screw II 804, the contact time of the pushing column and the two ship-shaped plates II 803 is further controlled, when the two ship-shaped plates II 803 are extruded, the two ship-shaped plates II 803 move outwards, and then the extruding column II 802 extrudes the, when the sensor II 10 is extruded, the sensor II 10 controls the telescopic end of the telescopic mechanism II 704 to move downwards, the sensor II 10 is connected with the telescopic mechanism II 704 through a conventional electric control means in the field, so that the heating cavity 705 is buckled on the processing barrel 303 to be heated, the length of the ship-shaped plate II 803 is controlled, the time for buckling the heating cavity 705 on the processing barrel 303 is further controlled, and the heating time is further controlled, when the pulling column 404 moves to the front side, because the movement of the pulling column 404 is circular movement, when the sliding support 102 does not limit the pushing column 403 any more, the pulling column 404 recovers circular movement, the pulling column 404 is separated from the heating slide block 701, the heating slide block 701 is reset under the action of the compression spring I, and the next processing barrel 303 is further conveniently heated; as the front side of the device is moved to processing mechanism 3 shown in fig. 1, when no longer receiving the extrusion of installation frame 101, compression spring II promotes processing mechanism 3 and moves to the outside, make material returned cone pulley 301 and material returned arc board 1103 contact, material returned arc board 1103 promotes material returned cone pulley 301 and rotates, material returned cone pulley 301 drives a section of thick bamboo 303 upset, make the raw materials in it pour out, and then make things convenient for next endless motion processing, start the height that material returned arc board 1103 can be adjusted to III 1101 of telescopic machanism, device repetitive motion can high-efficiently process building cement.

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 (10)

1. A method for processing building cement is characterized in that: the method comprises the following steps:

the method comprises the following steps: the conversion mechanism (2) drives the plurality of processing mechanisms (3) to move, and when the processing mechanisms (3) move to the two sides of the device bracket (1), the processing mechanisms (3) are limited by the device bracket (1) to move so that the processing mechanisms (3) sequentially pass through the plurality of feeding mechanisms (6);

step two: different cement processing raw materials are sequentially placed in the plurality of feeding mechanisms (6), and the plurality of feeding mechanisms (6) feed various raw materials into the processing mechanism (3) in proportion;

step three: the conversion mechanism (2) drives the processing mechanism (3) to pass through the heating mechanism (7), and the heating mechanism (7) carries out heating treatment on various raw materials in the processing mechanism (3);

the building cement processing method further relates to a building cement processing device, the building cement processing device comprises a device support (1), a conversion mechanism (2), a processing mechanism (3), a feeding mechanism (6) and a heating mechanism (7), the conversion mechanism (2) is connected to the device support (1), the conversion mechanism (2) is rotatably connected with the two processing mechanisms (3), torsion springs are fixedly connected between the two processing mechanisms (3) and the conversion mechanism (2), the feeding mechanism (6) is provided with a plurality of feeding mechanisms, the feeding mechanisms (6) are fixedly connected to one side of the device support (1), the heating mechanism (7) is slidably connected to the other side of the device support (1), and a compression spring I is fixedly connected between the heating mechanism (7) and the device support (1).

2. The method for processing building cement according to claim 1, wherein: the device support (1) comprises an installation frame (101), a sliding support (102), friction strips (103) and an installation support (104), wherein the sliding support (102) is fixedly connected to the right side of the installation frame (101), the friction strips (103) are fixedly connected to the left side and the right side of the installation frame (101), and the installation support (104) is fixedly connected to the installation frame (101).

3. The method for processing building cement according to claim 2, wherein: the conversion mechanism (2) comprises a conversion motor (201), a conversion shaft (202), a sliding cylinder I (203) and a sliding column I (204), the conversion motor (201) is fixedly connected to an installation frame (101), the conversion shaft (202) is rotatably connected to the installation frame (101), the conversion shaft (202) is in transmission connection with an output shaft of the conversion motor (201), the conversion shaft (202) is fixedly connected with two sliding cylinders I (203), the two sliding cylinders I (203) are all in sliding connection with the sliding column I (204), and a compression spring II is fixedly connected between the sliding column I (204) and the sliding cylinder I (203).

4. The method for processing building cement according to claim 3, wherein: processing agency (3) are including material returned cone pulley (301), collar (302), a processing section of thick bamboo (303), processing axle (304), stirring vane (305) and friction pulley (306), fixedly connected with collar (302) on material returned cone pulley (301), fixedly connected with processing section of thick bamboo (303) on collar (302), processing section of thick bamboo (303) internal rotation is connected with processing axle (304), a plurality of stirring vane (305) of fixedly connected with on processing axle (304), lower extreme fixedly connected with friction pulley (306) of processing axle (304), all rotate on two slip columns I (204) and be connected with material returned cone pulley (301), fixedly connected with torsional spring between material returned cone pulley (301) and slip column I (204).

5. The method for processing building cement according to claim 4, wherein: building cement processingequipment still includes pushing mechanism (4), pushing mechanism (4) are including sliding cylinder II (401), slip post II (402), promote post (403) and pulling post (404), sliding cylinder II (401) are provided with two, equal sliding connection has slip post II (402) on two sliding cylinder II (401), fixedly connected with compression spring III between slip post II (402) and the sliding cylinder II (401), equal fixedly connected with promotes post (403) and pulling post (404) on two slip post II (402), equal fixed connection on two sliding cylinder II (401) is on transfer shaft (202).

6. The method for processing building cement according to claim 5, wherein: the building cement processing device further comprises an extrusion mechanism I (5) and a sensor I (9), the extrusion mechanism I (5) comprises an extrusion frame I (501), a ship-shaped plate I (502), locking screws I (503) and extrusion columns I (504), the extrusion frame I (501) is connected with the two ship-shaped plates I (502) in a sliding mode, the extrusion frame I (501) is connected with the two locking screws I (503) through threads, the inner sides of the two locking screws I (503) are respectively propped against the two ship-shaped plates I (502), the extrusion columns I (504) are fixedly connected onto the extrusion frame I (501), the extrusion mechanism I (5) and the sensor I (9) are both provided with a plurality of compression springs IV, the extrusion columns I (504) are all in sliding connection on the left side of the installation frame (101), the sensor I (9) are all in fixed connection on the left side of the installation frame (101), and compression springs IV are all fixedly connected between the extrusion columns I (504) and the installation frame (101), the sensors I (9) are respectively positioned on the outer sides of the extrusion columns I (504).

7. The method for processing building cement according to claim 6, wherein: feeding mechanism (6) are including feed tank (601), feed pipeline (602), telescopic machanism I (603) and feed baffle (604), lower extreme fixedly connected with feed pipeline (602) of feed tank (601), fixedly connected with telescopic machanism I (603) on feed tank (601), telescopic machanism I (603)'s flexible end fixedly connected with feed baffle (604), feed baffle (604) sliding connection is in feed tank (601), a plurality of feed tanks of fixedly connected with (601) are gone up in installing support (104), a plurality of telescopic machanism I (603) are connected with a plurality of sensors I (9) respectively.

8. The method for processing building cement according to claim 7, wherein: heating mechanism (7) are including heating slider (701), heating traveller (702), heating support (703), telescopic machanism II (704) and heating cavity (705), heating slider (701) sliding connection is on sliding support (102), fixedly connected with heating traveller (702) on heating slider (701), fixedly connected with heating support (703) on heating slider (701), fixedly connected with telescopic machanism II (704) on heating support (703), telescopic end fixedly connected with heating cavity (705) of telescopic machanism II (704), fixedly connected with compression spring I between heating slider (701) and sliding support (102).

9. The method for processing building cement according to claim 8, wherein: the building cement processing device further comprises an extrusion mechanism II (8), a sensor II (10) and a material returning mechanism (11), wherein the extrusion mechanism II (8) comprises an extrusion frame II (801), an extrusion column II (802), a ship-shaped plate II (803) and locking screws II (804), the extrusion frame II (801) is fixedly connected with the extrusion column II (802), the extrusion frame II (801) is slidably connected with two ship-shaped plates II (803), the extrusion frame II (801) is connected with the two locking screws II (804) through threads, the inner sides of the two locking screws II (804) are respectively propped against the two ship-shaped plates II (803), the extrusion column II (802) is slidably connected onto the sliding support (102), a compression spring V is fixedly connected between the extrusion column II (802) and the sliding support (102), the sensor II (10) is fixedly connected onto the sliding support (102), and the sensor II (10) is positioned on the outer side of the extrusion column II (802), sensor II (10) and telescopic machanism II (704) are connected, and material returned mechanism (11) are served fixedly connected with material returned pole (1102) including telescopic machanism III (1101), material returned pole (1102) and material returned arc board (1103), telescopic machanism III (1101) is flexible, and material returned pole (1102) is gone up fixedly connected with material returned arc board (1103), and telescopic machanism III (1101) fixed connection is on installing support (104).

10. The construction cement processed by using a construction cement processing method according to claim 9, characterized in that: the building cement comprises the following components in parts by weight: 67-70 parts of limestone; 10-15 parts of clay; 0.5 to 1 part of iron ore; 9 to 11 portions of coal.

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