CN214159286U

CN214159286U - Raw material efficient blending device for producing heat-insulating refractory bricks

Info

Publication number: CN214159286U
Application number: CN202022779864.1U
Authority: CN
Inventors: 冯明赟
Original assignee: Xinghua Daduo Thermal Insulation Material Co Ltd
Current assignee: Harbin Dahua Refractory Materials Co ltd
Priority date: 2020-11-26
Filing date: 2020-11-26
Publication date: 2021-09-10
Anticipated expiration: 2030-11-26

Abstract

The utility model relates to a resistant firebrick production technical field discloses a high-efficient blending device of raw materials for production of thermal-insulated resistant firebrick, the top fixedly connected with feed mechanism of compounding box, and the inboard of compounding box is located top position department fixedly connected with compounding pipeline, the inboard of compounding pipeline is located middle part position department and rotates and be connected with the transmission main shaft, the outside of transmission main shaft is fixed with the mixing oar, the inboard of compounding box is located bottom position department symmetric connection and carries the oar by screw. The utility model discloses a can carry out autonomic confined feed mechanism to the inlet pipe port, can seal the feed inlet of blending unit and handle, and then avoid resistant firebrick raw materials to appear the dust in the blending in-process and the condition that looses outward, and in the blending in-process, through the preliminary stirring compounding of compounding oar to resistant firebrick raw materials, under the auger delivery stirring once more of auger delivery oar, can carry out the efficient to resistant firebrick raw materials and thoughtlessly join in marriage the processing.

Description

Raw material efficient blending device for producing heat-insulating refractory bricks

Technical Field

The utility model relates to a resistant firebrick production technical field specifically is a high-efficient blending device of raw materials for heat-insulating refractory brick production.

Background

The refractory bricks are made of refractory materials with certain shapes and sizes, and can be divided into fired bricks, unfired bricks, fused cast bricks and refractory heat-insulating bricks according to the preparation process method, and can be divided into standard type bricks, ordinary bricks, special-shaped bricks and the like according to the shapes and sizes, can be used as high-temperature building materials and structural materials of construction kilns and various thermal equipment, can bear various physical and chemical changes and mechanical actions at high temperature, and the raw materials of the refractory bricks need to be mixed and processed in the production and processing process of the refractory bricks.

However, the raw material mixing device for producing the refractory bricks in the market at present has some defects, the traditional mixing device has a single structure and low mixing production efficiency, and dust generated by mixing is easy to disperse during the raw material mixing process, so that the working environment of workers is affected. Therefore, the technical personnel in the field provide a raw material high-efficiency mixing device for producing the heat-insulating refractory bricks, so as to solve the problems in the background technology.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a thermal-insulated resistant firebrick production is with high-efficient blending device of raw materials to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a raw material high-efficiency blending device for producing heat-insulating refractory bricks comprises a material mixing box body, a feeding mechanism is fixedly connected above the material mixing box body, and the inner side of the mixing box body is fixedly connected with a mixing pipeline at the top end position, the inner side of the mixing pipeline is rotatably connected with a transmission main shaft at the middle position, a mixing paddle is fixed on the outer side of the transmission main shaft, a transmission motor is fixed at the middle position below the mixing pipeline, and the material conveying pipes are symmetrically connected at the positions of two ends below the material mixing pipeline, the spiral conveying propellers are symmetrically connected at the position of the bottom end inside the material mixing box body, a conveying motor is fixed at the position of one side of the mixing box body at the bottom end, a transmission gear is fixed at one end of the spiral conveying paddle, support foot frames are symmetrically fixed at the four corner positions below the material mixing box body, and a material outlet is formed in the middle position below the material mixing box body;

feed mechanism fixes the locating support in compounding box top including the symmetry, the inboard symmetry of locating support is fixed with the inlet pipe, and the front side symmetry of locating support is fixed with the atmospheric pressure push rod, one side of inlet pipe is connected with left side closed door, and the opposite side of inlet pipe is connected with right side closed door, left side closed door passes through closed push rod with right side closed door and is connected.

As a further aspect of the present invention: the quantity of inlet pipe is two sets of, and the inlet pipe is symmetrical arrangement each other for the horizontal central line of locating support.

As a further aspect of the present invention: the left side is closed the door and is located middle part position department all to be provided with the round pin axle around, and the left side is closed the door and is connected with the closed push rod through the round pin axle, both sides are located bottom position department around the right side is closed the door and all are provided with the axis of rotation, and the right side is closed the door and is connected with the closed push rod through the axis of rotation.

As a further aspect of the present invention: the quantity of mixing oar is three groups, and the interval distance between the mixing oar is the same.

As a further aspect of the present invention: the number of the material conveying pipes is two, and the material conveying pipes are symmetrically arranged in a Y shape relative to the horizontal central line of the material mixing pipeline.

As a further aspect of the present invention: the number of spiral conveying oars is two sets of, and the spiral conveying oars are symmetrically meshed through the transmission gear and rotate.

As a further aspect of the present invention: the spiral conveying propeller takes a center line as a boundary, and positive and negative conveying blades which are symmetrically arranged are arranged on two sides of the center line.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses a can carry out autonomic confined feed mechanism to the inlet pipe port, can seal the feed inlet of blending device and handle, and then avoid resistant firebrick raw materials to appear the condition that the dust looses outward in the blending process, ensure staff's operational environment's clean and tidy nature, can prevent that the dust from loosing outward and influencing the healthy of staff simultaneously, and in the blending process, through the preliminary stirring compounding of compounding oar to resistant firebrick raw materials, under the spiral transport stirring once more of spiral transport oar, can carry out efficient blending processing to resistant firebrick raw materials.

Drawings

FIG. 1 is a schematic structural diagram of a raw material efficient mixing device for producing heat-insulating refractory bricks;

FIG. 2 is a schematic structural diagram of the interior of a raw material efficient mixing device for producing heat-insulating refractory bricks;

FIG. 3 is a schematic structural diagram of a feeding mechanism in a raw material efficient mixing device for producing heat-insulating refractory bricks.

In the figure: 1. a mixing box body; 2. positioning the bracket; 3. an air pressure push rod; 4. a feed pipe; 5. a conveying motor; 6. a transmission gear; 7. a discharge outlet; 8. a supporting foot rest; 9. closing the push rod; 10. a left side closure door; 11. a right side closure door; 12. a screw conveying paddle; 13. a transmission main shaft; 14. a mixing paddle; 15. a mixing pipeline; 16. a drive motor; 17. a delivery pipe.

Detailed Description

Referring to fig. 1 to 3, in the embodiment of the present invention, a raw material high efficiency blending device for producing heat insulation refractory bricks comprises a material mixing box 1, a feeding mechanism is fixedly connected above the material mixing box 1, the feeding mechanism comprises a positioning bracket 2 symmetrically fixed above the material mixing box 1, a feeding pipe 4 is symmetrically fixed on the inner side of the positioning bracket 2, an air pressure push rod 3 is symmetrically fixed on the front side of the positioning bracket 2, one side of the feeding pipe 4 is connected with a left side closing door 10, the other side of the feeding pipe 4 is connected with a right side closing door 11, the left side closing door 10 is connected with the right side closing door 11 through a closing push rod 9, the feeding pipes 4 are two groups, the feeding pipes 4 are symmetrically arranged relative to the horizontal center line of the positioning bracket 2, pin shafts are arranged at the middle positions of the front side and the rear side of the left side closing door 10, and the left side closing door 10 is connected with the closing push rod 9 through a pin shaft, both sides lie in bottom position department around the right side closed door 11 and all are provided with the axis of rotation, and the right side closed door 11 passes through the axis of rotation and is connected with closed push rod 9, when mixing refractory brick raw materials, will be able to bear or endure firebrick raw materials and drop into in compounding pipeline 15 through inlet pipe 4, after putting in and finishing, the flexible end of atmospheric pressure push rod 3 stretches out, promote closed push rod 9 and slide forward, in the closed push rod 9 process that slides forward, drive left side closed door 10 and the rotation of right side closed door 11 symmetry, seal the processing to the feed port of inlet pipe 4, avoid resistant firebrick raw materials the condition that the dust was scattered outward to appear in mixing the in-process.

A material mixing pipeline 15 is fixedly connected at the top end position of the inner side of the material mixing box body 1, a transmission main shaft 13 is rotatably connected at the middle position of the inner side of the material mixing pipeline 15, a material mixing paddle 14 is fixed at the outer side of the transmission main shaft 13, a transmission motor 16 is fixed at the middle position of the lower part of the material mixing pipeline 15, and the material conveying pipes 17 are symmetrically connected at the positions of two ends below the material mixing pipeline 15, the number of the material mixing paddles 14 is three, the interval distance between the mixing paddles 14 is the same, the number of the material conveying pipes 17 is two, and the material conveying pipes 17 are symmetrically arranged in a Y shape relative to the horizontal central line of the mixing pipeline 15, in the process of mixing the raw materials of the refractory bricks, the transmission motor 16 works to drive the transmission main shaft 13 to rotate, synchronously drive the mixing paddles 14 to rotate, the raw materials of the refractory bricks are preliminarily mixed, and then the preliminarily mixed raw materials of the refractory bricks are discharged to the two ends of the spiral conveying paddle 12 through the material conveying pipes 17 which are symmetrically arranged in a Y shape.

The inner side of the material mixing box body 1 is symmetrically connected with screw conveying propellers 12 at the bottom position, one side of the material mixing box body 1 is fixed with a conveying motor 5 at the bottom position, one end of each screw conveying propeller 12 is fixed with a transmission gear 6, supporting foot rests 8 are symmetrically fixed at four corner positions below the material mixing box body 1, a discharge hole 7 is arranged at the middle position below the material mixing box body 1, the number of the screw conveying propellers 12 is two, the screw conveying propellers 12 are symmetrically meshed and rotate through the transmission gear 6, the screw conveying propellers 12 are bounded by a central line, positive and negative conveying blades which are symmetrically arranged are arranged on two sides of the central line, when the initially mixed refractory brick raw material is conveyed to two ends of the screw conveying propellers 12, the conveying motor 5 works, the screw conveying propellers 12 are driven to symmetrically rotate under the symmetrical meshing of the transmission gear 6, and the positive and negative conveying blades which are symmetrically arranged on the screw conveying propellers 12 are synchronously and symmetrically arranged on the screw conveying propellers 12, The reverse conveying paddle is used for carrying out spiral stirring conveying on the raw materials of the refractory bricks, symmetrically conveying the raw materials of the refractory bricks to the discharge opening 7 and discharging the raw materials of the refractory bricks to the outside through the discharge opening 7.

The utility model discloses a theory of operation is: when the raw materials of the refractory bricks are mixed, the raw materials of the refractory bricks are put into a mixing pipeline 15 through a feeding pipe 4, after the putting is finished, the telescopic end of an air pressure push rod 3 extends out to push a closed push rod 9 to slide forwards, a left side closed door 10 and a right side closed door 11 are driven to symmetrically rotate in the forward sliding process of the closed push rod 9, the feeding port of the feeding pipe 4 is sealed, the condition that dust is scattered outwards in the mixing process of the raw materials of the refractory bricks is avoided, further, in the mixing process of the raw materials of the refractory bricks, a transmission motor 16 works to drive a transmission main shaft 13 to rotate, a mixing paddle 14 is synchronously driven to rotate, the raw materials of the refractory bricks are preliminarily mixed and treated, the preliminarily mixed raw materials of the refractory bricks are discharged to the two ends of a spiral conveying paddle 12 through a conveying pipe 17 which is symmetrically arranged in a Y shape, when the preliminarily mixed raw materials of the refractory bricks are conveyed to the two ends of the spiral conveying paddle 12, the conveying motor 5 works, under the symmetrical meshing of the transmission gear 6, the screw conveying paddle 12 is driven to symmetrically rotate, the refractory brick raw materials are synchronously conveyed to the discharge hole 7 in a spiral type stirring mode through the forward conveying paddle and the reverse conveying paddle which are symmetrically arranged on the screw conveying paddle 12, and the refractory brick raw materials are symmetrically conveyed to the discharge hole 7 and are discharged outside through the discharge hole 7.

The above-mentioned, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims

1. The raw material efficient blending device for producing the heat-insulating refractory bricks comprises a mixing box body (1) and is characterized in that a feeding mechanism is fixedly connected above the mixing box body (1), a mixing pipeline (15) is fixedly connected at the position of the top end of the inner side of the mixing box body (1), a transmission main shaft (13) is rotatably connected at the position of the middle part of the inner side of the mixing pipeline (15), a mixing paddle (14) is fixed at the outer side of the transmission main shaft (13), a transmission motor (16) is fixed at the position of the middle part of the lower part of the mixing pipeline (15), conveying pipes (17) are symmetrically connected at the positions of the two ends of the lower part of the mixing pipeline (15), a spiral conveying paddle (12) is symmetrically connected at the position of the bottom end of the inner side of the mixing box body (1), and a conveying motor (5) is fixed at the position of the bottom end of one side of the mixing box body (1), a transmission gear (6) is fixed at one end of the spiral conveying paddle (12), supporting foot frames (8) are symmetrically fixed at four corner positions below the mixing box body (1), and a discharge hole (7) is formed in the middle position below the mixing box body (1);

feed mechanism fixes locating support (2) in compounding box (1) top including the symmetry, the inboard symmetry of locating support (2) is fixed with inlet pipe (4), and the front side symmetry of locating support (2) is fixed with atmospheric pressure push rod (3), one side of inlet pipe (4) is connected with left side closed door (10), and the opposite side of inlet pipe (4) is connected with right side closed door (11), left side closed door (10) are connected through sealing push rod (9) with right side closed door (11).

2. The raw material high-efficiency mixing device for producing the heat-insulating refractory bricks is characterized in that the number of the feeding pipes (4) is two, and the feeding pipes (4) are symmetrically arranged relative to the horizontal center line of the positioning bracket (2).

3. The raw material efficient mixing device for producing the heat-insulating refractory bricks, as recited in claim 1, wherein the front and rear sides of the left side closing door (10) are provided with pin shafts at the middle positions, the left side closing door (10) is connected with the closing push rod (9) through the pin shafts, the front and rear sides of the right side closing door (11) are provided with rotating shafts at the bottom positions, and the right side closing door (11) is connected with the closing push rod (9) through the rotating shafts.

4. The raw material efficient mixing device for producing the heat-insulating refractory bricks, as recited in claim 1, is characterized in that the number of the mixing paddles (14) is three, and the spacing distances between the mixing paddles (14) are the same.

5. The raw material efficient mixing device for producing the heat-insulating refractory bricks, as recited in claim 1, wherein the number of the material conveying pipes (17) is two, and the material conveying pipes (17) are arranged symmetrically in a Y shape relative to the horizontal center line of the material mixing pipeline (15).

6. The raw material efficient mixing device for producing the heat-insulating refractory bricks, as recited in claim 1, is characterized in that the number of the screw conveying paddles (12) is two, and the screw conveying paddles (12) are symmetrically meshed and rotated through the transmission gear (6).

7. The raw material efficient mixing device for producing the heat-insulating refractory bricks, as recited in claim 1, characterized in that the screw conveying paddles (12) are bounded by a midline, and positive and negative conveying paddles are symmetrically arranged on two sides of the midline.