CN214095545U - Special stand of reaction sintering carborundum kiln - Google Patents

Abstract

The utility model relates to a special stand column for a reaction sintering silicon carbide kiln, which comprises a stand column main body and a plurality of backing plates; the main body of the upright post is in a circular tube shape; the upright post main body is provided with a plurality of hole groups for connecting with a kiln car bracket; the wall surface of the inner cavity of the upright post main body is provided with a plurality of reinforcing ribs; the backing plate is fixed on the lower side of the mounting hole. The upright post has reasonable structure, high density and uniform wall thickness; the compressive strength is high; the high temperature resistant 1250 ℃ can not deform, crack, bend and collapse after long-term use and operation.

Description

Special stand of reaction sintering carborundum kiln

Technical Field

The utility model relates to a ceramic kiln technical field especially relates to a special stand of reaction sintering carborundum kiln.

Background

The bearing upright post is a kiln car support for various kilns such as sanitary porcelain, daily porcelain, microcrystalline glass, foamed ceramic and the like, plays an important bearing and supporting role, and sintering of various main beams, auxiliary beams, shed plates, sintered products and the like is completed under the support of the bearing upright post. At present, the foamed ceramic industry is mostly single-layer or two-layer supporting columns, and is square or huge, the structure is single, and the actual use requirements cannot be met.

Disclosure of Invention

The utility model aims to solve the technical problem of providing a special stand column for a reaction sintering silicon carbide kiln, wherein the main body of the stand column is changed from the prior square shape to the circular shape, the structure is reasonable, the compressive strength is high, the strength is maintained, and the material is saved; the wall thickness is uniform by adopting an extrusion molding process for processing; and (4) high temperature resistance.

In order to solve the technical problem, the technical scheme of the utility model is that: a column special for a reaction sintering silicon carbide kiln comprises

The upright post main body is in a circular tube shape; the upright post main body is provided with a plurality of hole groups for connecting with a kiln car bracket; the wall surface of the inner cavity of the upright post main body is provided with a plurality of reinforcing ribs;

and a plurality of backing plates which are fixed on the lower side surfaces of the mounting holes.

Preferably, the plurality of hole groups are uniformly distributed in the axial direction of the column body.

Preferably, each hole group includes two mounting holes, and the two mounting holes correspond to each other at the position of the column main body and communicate with each other in the radial direction of the column main body.

As preferred technical scheme, the mounting hole is the square hole, and the edges and corners of mounting hole carry out the fillet, form first fillet connecting portion.

As the preferred technical scheme, gaps are reserved between the two first fillet connecting parts positioned on the two sides of the base plate and the base plate.

As a preferable technical scheme, the shapes of the two end parts of the backing plate are matched with the shape of the lower side surface of the mounting hole; two side edges of the base plate connecting surface are chamfered to form a second fillet connecting part.

Preferably, the material of the backing plate is the same as that of the column main body.

As preferred technical scheme, the cross section of strengthening rib is arc, and strengthening rib and stand main part integrated into one piece.

In the prior art, the upright post main body with a square or rectangular cross section is generally adopted, and in the sintering operation process, when the upright post main body runs to the position of a kiln flame nozzle, flame can be blocked, the flame can not be sprayed into a kiln car, and a product can not be sintered; therefore, the effective time of the flame sprayed into the kiln car is reduced, the heat entering the kiln car is correspondingly reduced, and the sintering quality is influenced; in order to ensure the sintering quality, the sintering time needs to be prolonged correspondingly, and the energy consumption of the kiln is high. The utility model provides a cross section is circular shape stand main part innovatively, and when the position of stand main part process kiln flame nozzle, flame can be sprayed along the outside arc surface of stand main part, walks around the stand main part and sprays in the kiln car to improve thermal application efficiency, reduce the energy consumption, improve sintering quality. The stand column special for the reaction sintering silicon carbide kiln has the advantages of reasonable structure, high density and uniform wall thickness; the compressive strength is high; the high temperature resistant 1250 ℃ can not deform, crack, bend and collapse after long-term use and operation.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

FIG. 1 is a schematic structural view of a reaction sintered column;

FIG. 2 is an enlarged partial view of area B of FIG. 1;

FIG. 3 is a cross-sectional view of section A-A of FIG. 1;

FIG. 4 is an enlarged partial view of area C of FIG. 3;

FIG. 5 is a schematic view of the structure of the column body extrusion die;

FIG. 6 is a cross-sectional view taken along section D-D of FIG. 5;

FIG. 7 is a schematic view of the clamping of the stud body on the engraver;

fig. 8 is a schematic view of the process of machining the mounting hole in the column body.

Detailed Description

A reaction sintering carborundum kiln special column, as shown in figure 1 and figure 3, comprises a column main body 1, wherein the column main body 1 is tubular, and an inner cavity extending along the axial direction of the column main body is arranged in the column main body 1; the cross section of the column body 1 is circular.

The upright post main body 1 is provided with a plurality of hole groups 3, the hole groups 3 are uniformly distributed in the axial direction of the upright post main body 1, and the number of the hole groups 3 can be set as required in actual use; as shown in fig. 2, the column body 1 is provided with three hole groups 3.

Each hole group 3 includes two mounting holes 31, and the two mounting holes 31 correspond to each other at the position of the column body 1 and communicate with each other in the radial direction of the column body 1. When the vertical column is used, one end of the kiln car support penetrates through the two mounting holes 31 of the same hole group 3, so that the connection strength of the vertical column main body 1 and the kiln car support is increased, and the use stability is guaranteed.

As shown in fig. 1, the mounting hole 31 is a square hole, and is suitable for a square beam; when the beam with other shape is used in practical use, the mounting hole 31 can be adjusted according to the requirement, for example, when the connecting part of the beam is cylindrical, the mounting hole 31 can be a circular hole; when the connecting portion of the beam is trapezoidal, the mounting hole 31 may be a trapezoidal hole or the like.

In order to meet the pressure resistance requirement of the column body 1, prevent the mounting hole 31 from cracking under high temperature load, and ensure the strength of the column body 1, as shown in fig. 2, the corners of the mounting hole 31 are respectively rounded to form first rounded connecting portions 11, so as to remove stress and prevent cracking from the corners.

In order to ensure that the strength of the upright post main body 1 is not reduced, a plurality of reinforcing ribs 4 are arranged on the wall surface of the inner cavity. Preferably, as shown in fig. 3 and 4, two reinforcing ribs 4 are provided on the wall surface of the inner cavity, and the two reinforcing ribs 4 and the two mounting holes 31 are provided at intervals in the circumferential direction of the column body 1, that is, the two reinforcing ribs 4 are located on the left and right sides of the mounting holes 31.

The cross section of the reinforcing rib 4 is preferably circular arc-shaped, and the thickness consistency of the reinforcing rib 4 is good; preferably, the reinforcing ribs 4 are integrally formed with the column body 1.

The upright post also comprises a plurality of backing plates 2, and the materials of the backing plates 2 are the same as those of the upright post main body 1. The backing plate 2 is fixed on the lower side surface of the mounting hole 31, so that the compression-resistant contact surface of the kiln car bracket and the upright post main body 1 is increased; as shown in fig. 2 and 3, the backing plate 2 is an elongated plate, and most preferably, the thickness of the backing plate 2 is 8 mm. Two ends of the backing plate 2 are arc-shaped and are matched with the lower side surface of the mounting hole 31 in shape, so that the contact area between the backing plate 2 and the lower side surface of the mounting hole 31 is ensured to be the largest. The side edge of the connecting surface of the backing plate 2 is chamfered to form a second fillet connecting part 21. Every backing plate 2 is fixed simultaneously in two mounting holes 31 of same punch combination 3, backing plate 2 atress is too big when avoiding stand main part 1 to bear, two angles in the bottom cause the fracture because of stress is too big, reserve the gap between backing plate 2 and first fillet connecting portion 11, the minimum width in gap is 1.5mm, contactless between first fillet connecting portion 11 that so can realize and the second fillet connecting portion 21, guaranteed backing plate 2 atress backward push down and the first fillet connecting portion 11 atress of both sides.

The preparation method of the upright post comprises the following steps

The method comprises the following steps: measuring raw materials; the weight ratio of each material is respectively

Silicon carbide micropowder with the particle size of 1000 meshes: 12 parts of (1);

silicon carbide micropowder with the grain diameter of 5000 meshes: 6 parts of (1);

silicon carbide micropowder with the particle size of 650 meshes: 25 parts of (1);

silicon carbide micro powder with the particle size of 300 meshes: 45 parts of (1);

carbon powder: 13 parts;

sodium carboxymethylcellulose with a particle size of 80 meshes: 2.5-3 parts;

polyvinylpyrrolidone K30 with a particle size of 120 mesh: 3.5-4 parts;

step two: mixing the raw materials;

fully mixing the weighed raw materials;

step three: pouring the mixed raw materials into a kneader, starting the kneader, adding 12-13 parts of deionized water, kneading, and taking out the mixture after the mixture is in a mud shape;

step four: manufacturing a column blank and a base plate blank;

the pug is extruded to form a column blank, and the column blank comprises a column main body 1 and two reinforcing ribs 4.

Specifically, the kneaded pug-like material is fed into a vacuum screw extruder and extruded through a die, as shown in fig. 5 and 6, which is composed of an outer die body 5 and a core die 6, and an extrusion passage is formed between the core die 6 and the outer die body 5. The upright post blank body formed by extrusion comprises an upright post main body 1 and two reinforcing ribs 4; due to the adoption of the extrusion molding process, the molded upright post main body 1 and the reinforcing ribs 4 have uniform wall thickness, high strength and stable and reliable performance.

The mud material is manufactured into a base plate blank through a slip casting process.

Specifically, a blank of the backing plate 2 is manufactured by slip casting through a plaster mold.

Step five: the upright post blank and the base plate blank are dried at normal temperature, low temperature and high temperature in sequence;

drying at normal temperature: naturally airing the stand column blank and the base plate blank for 2-3 hours;

and (3) low-temperature drying: placing the column blank and the pad blank into a low-temperature drying chamber, and heating the temperature of the low-temperature drying chamber from room temperature to 40 ℃ for 2 hours; then keeping the temperature for 12 hours, namely maintaining the temperature of the low-temperature drying chamber at 40 ℃ for 12 hours;

and (3) high-temperature drying: putting the column blank and the pad blank into a high-temperature drying chamber, wherein the temperature of the high-temperature drying chamber is increased from 40 ℃ to 70 ℃, and the temperature rise time is 4 hours; then keeping the temperature for 48 hours, namely keeping the temperature of the high-temperature drying chamber at 70 ℃ for 48 hours;

step six: mounting holes are formed in the column blank;

when the mounting holes 31 are formed, the three mounting holes 31 on the same side of the column body 1 are required to be positioned on a straight line, so that symmetry is ensured, and the heights of the two mounting holes 31 in the same hole group 3 are consistent. As shown in fig. 7 and 8, the operation of opening the mounting hole 31 is performed on the engraving machine 72, and after the column blank is clamped and positioned on the engraving machine 72, the engraving machine head 75 is used to engrave the mounting hole 31 on the column body 1. Clamping of the column blank can be as shown in fig. 7, the end of the column blank is positioned by the end positioning clamp 71, the column body 1 is supported by the V-shaped fixing block 73, and the column body 1 is clamped by the positioning clamps 74.

The column blank is clamped and positioned once on the engraving machine 72, and then the two mounting holes 31 in the same hole group 3 are machined. As shown in fig. 8, the mounting hole 31 on the upper side is processed first, and after the process, the engraving machine head 75 passes through the mounting hole 31 to process another mounting hole 31 on the lower side, so that the column blank does not need to be turned over, two mounting holes 31 in the same hole group 3 are ensured to be on the same radial line, and the situation that the kiln car support cannot be installed due to the mutual dislocation of the two mounting holes 31 is avoided. And after finishing the processing of one hole group 3, clamping and positioning the upright post main body 1 again to finish the processing of other hole groups 3.

Step seven: installing a base plate 2;

coating the grout prepared in the third step on the connecting surface of the backing plate 2 and the mounting hole 31; the backing plate 2 is then glued to the underside of the mounting hole 31, leaving a gap between the backing plate 2 and each of the two vertical sides of the mounting hole 31, the gap having a minimum width of 1.5 mm.

Wherein, the downward side of the two ends of the backing plate 2 is coated with the slurry prepared in the third step, and the upward side of the mounting hole 31 is also uniformly coated with the slurry.

The first embodiment is as follows:

the preparation method of the upright post comprises the following steps

The method comprises the following steps: measuring raw materials; the weight ratio of each material is respectively

Silicon carbide micropowder with the particle size of 1000 meshes: 12 parts of (1);

silicon carbide micropowder with the grain diameter of 5000 meshes: 6 parts of (1);

silicon carbide micropowder with the particle size of 650 meshes: 25 parts of (1);

silicon carbide micro powder with the particle size of 300 meshes: 45 parts of (1);

carbon powder: 13 parts;

sodium carboxymethylcellulose with a particle size of 80 meshes: 2.5 parts;

polyvinylpyrrolidone K30 with a particle size of 120 mesh: 3.5 parts.

Step two: mixing the raw materials;

the measured raw materials are added into a V-shaped mixer to be stirred for 60 minutes and then taken out.

Step three: pouring the mixed raw materials into a kneader, starting the kneader, adding 12 parts of deionized water, kneading for 50 minutes, and taking out the mixture after the mixture is in a mud shape;

step four: manufacturing a column blank and a base plate blank;

adding the kneaded pug-like material into a vacuum screw extruder, and extruding and molding through a die to form an upright post blank comprising an upright post main body 1 and two reinforcing ribs 4;

and a blank body of the backing plate 2 is manufactured by slip casting through a gypsum mould.

Step five: the upright post blank and the base plate blank are dried at normal temperature, low temperature and high temperature in sequence;

drying at normal temperature: naturally airing the stand column blank and the base plate blank for 2-3 hours;

and (3) low-temperature drying: placing the column blank and the pad blank into a low-temperature drying chamber, heating the temperature of the low-temperature drying chamber from room temperature to 40 ℃ for 2 hours, and then keeping the temperature for 12 hours;

and (3) high-temperature drying: and (3) putting the column blank and the cushion plate blank into a high-temperature drying chamber, heating the temperature of the high-temperature drying chamber from 40 ℃ to 70 ℃ for 4 hours, and then keeping the temperature for 48 hours.

Step six: mounting holes are formed in the column blank; the opening of the plurality of mounting holes 31 is completed at one time.

Step seven: installing a base plate 2;

coating the grout formed in the third step on the connecting surface of the backing plate 2 and the mounting hole 31; the shim plate 2 is then glued to the underside of the mounting hole 31, leaving a gap of 1.5mm between the shim plate 2 and each of the two vertical sides of the mounting hole 31.

Example two:

the preparation method of the upright post comprises the following steps

The method comprises the following steps: measuring raw materials; the weight ratio of each material is respectively

Silicon carbide micropowder with the particle size of 1000 meshes: 12 parts of (1);

silicon carbide micropowder with the grain diameter of 5000 meshes: 6 parts of (1);

silicon carbide micropowder with the particle size of 650 meshes: 25 parts of (1);

silicon carbide micro powder with the particle size of 300 meshes: 45 parts of (1);

carbon powder: 13 parts;

sodium carboxymethylcellulose with a particle size of 80 meshes: 3 parts of a mixture;

polyvinylpyrrolidone K30 with a particle size of 120 mesh: 4 parts.

Step two: mixing the raw materials;

the measured raw materials are added into a V-shaped mixer to be stirred for 60 minutes and then taken out.

Step three: pouring the mixed raw materials into a kneader, starting the kneader, adding 12 parts of deionized water, kneading for 60 minutes, and taking out the mixture after the mixture is in a mud shape;

step four: manufacturing a column blank and a base plate blank;

adding the kneaded pug-like material into a vacuum screw extruder, and extruding and molding through a die to form an upright post blank comprising an upright post main body 1 and two reinforcing ribs 4;

and a blank body of the backing plate 2 is manufactured by slip casting through a gypsum mould.

Step five: the upright post blank and the base plate blank are dried at normal temperature, low temperature and high temperature in sequence;

drying at normal temperature: naturally airing the stand column blank and the base plate blank for 2-3 hours;

and (3) low-temperature drying: placing the column blank and the pad blank into a low-temperature drying chamber, heating the temperature of the low-temperature drying chamber from room temperature to 40 ℃ for 2 hours, and then keeping the temperature for 12 hours;

and (3) high-temperature drying: and (3) putting the column blank and the cushion plate blank into a high-temperature drying chamber, heating the temperature of the high-temperature drying chamber from 40 ℃ to 70 ℃ for 4 hours, and then keeping the temperature for 48 hours.

Step six: mounting holes are formed in the column blank;

the opening of the plurality of mounting holes 31 is completed at one time.

Step seven: installing a base plate 2;

the grout prepared in the third step is coated on the connecting surface of the backing plate 2, and the grout is uniformly coated on the connecting surface of the mounting hole 31; the shim plate 2 is then glued to the underside of the mounting hole 31, leaving a gap of 1.5mm between the shim plate 2 and each of the two vertical sides of the mounting hole 31.

The temperature is low in winter, and by adopting the preparation scheme, the parts of the sodium carboxymethylcellulose and the polyvinylpyrrolidone K30 are increased, and the mixing time is prolonged, so that the strength of the product is ensured.

Example three:

the preparation method of the upright column comprises

The method comprises the following steps: measuring raw materials; the weight portion ratio of each material is

Silicon carbide micropowder with the particle size of 1000 meshes: 12 parts of (1);

silicon carbide micropowder with the grain diameter of 5000 meshes: 6 parts of (1);

silicon carbide micropowder with the particle size of 650 meshes: 25 parts of (1);

silicon carbide micro powder with the particle size of 300 meshes: 45 parts of (1);

carbon powder: 13 parts;

sodium carboxymethylcellulose with a particle size of 80 meshes: 2.5 parts;

polyvinylpyrrolidone K30 with a particle size of 120 mesh: 3.5 parts.

Step two: mixing the raw materials;

the measured raw materials are added into a V-shaped mixer to be stirred for 60 minutes and then taken out.

Step three: pouring the mixed raw materials into a kneader, starting the kneader, adding 13 parts of deionized water, kneading for 50 minutes, and taking out the mixture after the mixture is in a mud shape;

step four: manufacturing a column blank and a base plate blank;

adding the kneaded pug-like material into a vacuum screw extruder, and extruding and molding through a die to form an upright post blank comprising an upright post main body 1 and two reinforcing ribs 4;

and a blank body of the backing plate 2 is manufactured by slip casting through a gypsum mould.

Step five: the upright post blank and the base plate blank are dried at normal temperature, low temperature and high temperature in sequence;

drying at normal temperature: naturally airing the stand column blank and the base plate blank for 2-3 hours;

and (3) low-temperature drying: placing the column blank and the pad blank into a low-temperature drying chamber, heating the temperature of the low-temperature drying chamber from room temperature to 40 ℃ for 2 hours, and then keeping the temperature for 12 hours;

and (3) high-temperature drying: and (3) putting the column blank and the cushion plate blank into a high-temperature drying chamber, heating the temperature of the high-temperature drying chamber from 40 ℃ to 70 ℃ for 4 hours, and then keeping the temperature for 48 hours.

Step six: mounting holes are formed in the column blank; the opening of the plurality of mounting holes 31 is completed at one time.

Step seven: installing a base plate 2;

coating the grout prepared in the third step on the connecting surface of the backing plate 2 and the mounting hole 31; the shim plate 2 is then glued to the underside of the mounting hole 31, leaving a gap of 1.5mm between the shim plate 2 and each of the two vertical sides of the mounting hole 31.

The temperature is high in summer, the water is quickly evaporated, and the weight proportion of the deionized water is properly increased so as to ensure the product quality.

Through the detection, the utility model discloses obtained goods density has reached 3.06g/cm full-length, has improved compressive strength. The upright post is changed from square to round, thereby ensuring that the strength is not reduced and saving materials. The utility model discloses an extrusion moulding technology, it is even to have reached the wall thickness, and strengthening rib 4 has improved the compressive strength of stand greatly. In order to ensure that the central planes of the 6 mounting holes 31 of the column body 1 are the same plane and meet the requirements of hole symmetry and hole height consistency, the 6 mounting holes 31 are processed at one time. In order to avoid the phenomenon that the two corners at the bottom of the mounting hole 31 are cracked due to overlarge stress caused by overlarge stress when the upright column bears the load, a 1.5mm wide gap is reserved at the two sides of the base plate 2 and the two first fillet connecting parts 11 of the mounting hole 31, and the base plate 2 is guaranteed to be pressed downwards after bearing the load and the two sides of the mounting hole 31 are not stressed.

The basic principles, main features and advantages of the present invention have been shown and described above. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (8)

1. The utility model provides a special stand of reaction sintering carborundum kiln which characterized in that: comprises that

The upright post comprises an upright post main body (1), wherein the upright post main body (1) is in a circular tube shape; the upright post main body (1) is provided with a plurality of hole groups (3) for connecting with a kiln car bracket; the wall surface of the inner cavity of the upright post main body (1) is provided with a plurality of reinforcing ribs (4);

and a plurality of backing plates (2), wherein the backing plates (2) are fixed on the lower side surfaces of the mounting holes (31).

2. The special column for the reaction sintering silicon carbide kiln as claimed in claim 1, wherein: the plurality of hole groups (3) are uniformly distributed in the axial direction of the column main body (1).

3. The special column for the reaction sintering silicon carbide kiln as claimed in claim 1, wherein: each hole group (3) comprises two mounting holes (31), and the two mounting holes (31) correspond to each other at the position of the upright post main body (1) and are communicated with each other in the radial direction of the upright post main body (1).

4. The special column for the reaction sintering silicon carbide kiln as claimed in claim 3, wherein: the mounting hole (31) is a square hole, and the edges and corners of the mounting hole (31) are rounded to form a first rounded connecting part (11).

5. The special column for the reaction sintering silicon carbide kiln as claimed in claim 4, wherein: gaps are reserved between the two first fillet connecting parts (11) positioned on the two sides of the backing plate (2) and the backing plate (2).

6. The special column for the reaction sintering silicon carbide kiln as claimed in claim 1, wherein: the shapes of the two end parts of the backing plate (2) are matched with the shape of the lower side surface of the mounting hole (31); two side edges of the connecting surface of the backing plate (2) are chamfered to form a second fillet connecting part (21).

7. The special column for the reaction sintering silicon carbide kiln as claimed in claim 1, wherein: the material of the backing plate (2) is the same as that of the column main body (1).

8. The special column for the reaction sintering silicon carbide kiln as claimed in claim 1, wherein: the cross section of the reinforcing rib (4) is arc-shaped, and the reinforcing rib (4) and the upright post main body (1) are integrally formed.

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