KR102031428B1 - Damage simulator for refractory and manufacture apparatus thereof - Google Patents

Abstract

The present invention relates to a refractory damage simulation tester and a manufacturing apparatus thereof.
Refractory damage simulation tester according to the present invention; a tester body for receiving a specimen therein; and a tester cover coupled to the tester body; And a protection unit provided inside the tester body and the tester cover to support the specimen, wherein the protection unit may be provided to be separated by a predetermined thickness.

Description

Refractory damage simulation tester and manufacturing apparatus thereof {DAMAGE SIMULATOR FOR REFRACTORY AND MANUFACTURE APPARATUS THEREOF}

The present invention relates to a refractory damage simulation tester and a manufacturing apparatus thereof.

In general, since the internal temperature of the blast furnace, blast furnace, etc. (hereinafter referred to as `` blast furnace '') in the steel process rises to about 1700 ℃, the interior of the blast furnace is provided with irregular refractory to protect the shelter.

These amorphous refractory materials are easily dissolved by physical and chemical reactions because they are in constant contact with molten metal and slag in the blast furnace. Since the melting loss of the amorphous refractory material varies according to the temperature inside the blast furnace, the components of the slag, and the atmosphere inside the blast furnace, the specimens of the same material and components as those of the actual refractory are put into a refractory tester that reproduces the blast furnace environment. The durability against melting hands will be evaluated.

1 shows a conventional refractory tester 10. The refractory tester 10 includes a lower body 11 for receiving the specimen 1 therein by the support filling body 17 and an upper body 12 engaged with the lower body and having a flame hole 16. do.

The lower body 11 and the upper body 12 are coupled to each other by a bolt 15 inserted into a bolt hole 14 provided in each and a nut 15a coupled to the bolt 15.

On the other hand, inside the lower body 11 and the upper body 12 is provided with an irregular refractory 13, respectively, the irregular refractory 13 has an upper portion corresponding to the flame hole 16 provided in the upper body 12 The hole 18 is provided.

Through the flame hole 16 and the upper hole 18, the reaction material (not shown) to react with the amorphous refractory 13 and the specimen 1 is introduced together with the flame, and the lower body 11 and the upper body 12 ) Heat until the temperature inside is at least equal to the temperature inside the actual blast furnace.

When the reaction is completed after a certain time, as shown in Figure 2, withdraw the bolt from the bolt hole 14 to separate the upper body 12 and the lower body (11 of Figure 1), and discharge the internal material into the upper hole 18 Then, the following tests may be performed. As the test is repeated, the irregular refractory 13 provided in the upper body 12 is deformed or damaged, so that the damaged irregular refractory 13 is removed, and the new irregular refractory 13 is removed. There is a problem of construction.

KR 10-2012-0073673 A (2012.07.05)

An object of the present invention is to shorten the test preparation time or period through the refractory damage simulation tester to enable continuous testing.

In addition, it is an object to facilitate the manufacture and maintenance of the refractory damage simulation tester, and to improve the convenience of the test.

The present invention relates to a refractory damage simulation tester and a manufacturing apparatus thereof.

Refractory damage simulation tester according to the present invention; a tester body for receiving the specimen therein; and a tester cover coupled to the tester body; and the tester body and the inside of the tester cover to support the specimen, a predetermined thickness A protection unit provided to be separated from each other; and fastening holes provided in the tester body and the tester cover, respectively; And a fastening bolt inserted into the fastening hole, wherein the protective unit includes: an upper refractory provided in the tester cover; And a detachable upper refractory provided inward from the upper refractory in the tester cover in the center direction of the tester cover and separated from the upper refractory. The separated upper refractory is formed by a reactant and a flame. A through hole into which contaminants to be introduced are introduced, and the specimen may be external to the through hole during testing.

Preferably, the protection unit, the lower refractory provided in the lower body of the tester; And a separate lower refractory provided on an upper portion of the lower refractory and separated from the lower refractory to contact the specimen.

Also preferably, the tester cover may include a flame inlet hole, and the upper refractory may include a through hole disposed on the same line as the flame inlet hole in a gravity direction.

Also preferably, the removable upper refractory may be provided to be coupled to the through hole of the upper refractory such that the through hole faces the flame inlet hole, and to increase in diameter as it moves away from the flame inlet hole.

Also preferably, the split top refractory may be provided such that its diameter increases linearly away from the flame inlet.

And preferably, the diameter of the outer circumference of the removable upper refractory and the diameter of the inner circumference of the upper refractory may be provided to have an intermediate fit or interference fit tolerance of each other.

On the other hand, the present invention as another aspect is a first mold having an outer surface corresponding to the inner surface of the removable upper refractory to manufacture the separate upper refractory of the refractory damage simulation tester; and a predetermined distance from the outer periphery of the first mold The second mold is spaced apart to form a gap with the first mold; including, but is provided to manufacture a refractory damage simulation tester which is provided to manufacture the removable upper refractory by filling the gap into the gap.

Preferably, the filler may be alumina.

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According to the present invention, the test preparation time or period is shortened to enable continuous refractory damage simulation test.

In addition, the reliability and convenience of the test is improved.

In addition, it is easy to manufacture and maintain a refractory damage simulation tester.

1 schematically shows a conventional refractory tester.
Figure 2 shows a damaged state of the upper body of a conventional refractory tester.
Figure 3 schematically shows the process of forming the upper body of a conventional refractory tester.
Figure 4 schematically shows a refractory damage simulation tester according to an embodiment of the present invention.
Figure 5 schematically shows the detached state of the tester cover of the refractory damage simulation tester according to an embodiment of the present invention.
Figure 6 schematically shows a refractory damage simulation tester according to an embodiment of the present invention.
7 schematically illustrates a process of forming a tester cover according to an exemplary embodiment of the present invention.
8 schematically illustrates a manufacturing apparatus of a refractory damage simulation tester according to an exemplary embodiment of the present invention.
Figure 9 schematically shows a separate top refractory formed by the apparatus for producing a refractory damage simulation tester according to an embodiment of the present invention.

In order to help the understanding of the description of the embodiments of the present invention, the elements described with the same reference numerals in the accompanying drawings are the same elements, and the related elements among the components that will act the same in each embodiment may be represented by the same or extended numbers. Notation is shown.

Further, in order to clarify the gist of the present invention, a description of elements and techniques well known by the prior art will be omitted, and hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

However, the spirit of the present invention is not limited to the embodiments presented, but may be proposed in other forms in which specific elements have been added, changed, or deleted by those skilled in the art, but are also included within the scope of the same spirit as the present invention. Leave it on.

In addition, hereinafter, all of the 'furnace' that can be used in a steel process, such as blast furnaces, converters will be described as a 'blast furnace'.

3 shows a typical upper body 12 coupled to a conventional lower body (11 in FIG. 1).

First, as shown in (a), through the flame hole 16 formed in the upper body 12 and the upper hole 18 formed in the amorphous refractory 13 corresponding to the flame hole 16, the flame and reactants ( When the test is started, the test is started. After a certain time, after the test is finished, the contaminant 20 remains on the inner surface of the amorphous refractory 13.

Such contaminants 20 may affect the following test results, or may cause damage to the upper body 12 if left unchecked, as shown in (b), in which the contaminant 20 and the contaminant 20 are fixed in a refractory. Some parts of (13) must be removed together.

Then, in order to reconstruct the remaining amorphous refractory 13, as shown in (c) and (d), the base 41 is supported, and the mold 40 and the filler are put together. Maintaining this state for about three days to complete the construction, drying and curing process, as shown in (e), to remove the mold 40 to complete the upper body 12, it is possible to perform a new test.

Using a conventional tester as described above requires at least three days of test preparation, and thus it is impossible to continuously perform the test, and the overall test progress is slowed, and thus the test and development period of the product is also delayed.

Therefore, the present invention, as shown in Figure 4, the tester body 110, the tester cover 120 coupled to the tester body 110, the tester body 110 and the tester cover 120 to accommodate the specimen therein Provided therein provides a refractory damage simulation tester 100 including a protection unit 130 for supporting the specimen.

In this case, the tester body 110 and the tester cover 120 may be provided in a circular shape, and a plurality of specimens (P of FIG. 6) may be placed in the circumferential direction of the tester body 110 and the tester cover 120. .

At this time, the protection unit 130 is provided to be separated by a predetermined thickness to separate the soiled portion (not shown) buried, so that it can be carried out continuously by combining the new protection unit prepared in advance do.

Preferably, the protection unit is provided in the lower refractory 131 provided on the lower body of the tester body 110, the removable lower refractory 132 mounted on the upper portion of the lower refractory 131, the tester cover 120 inside. The upper refractory 133 is located inside the upper refractory 133 in the direction of the center of the tester cover 120, the contact with the upper refractory 133 is usually in contact with the upper refractory 133 It may include a separate upper refractory 134 provided to maintain.

The combination of the upper refractory 133 and the separate upper refractory 134 may be possible by fitting tolerances or surface friction, and by using a carbon adhesive between the upper refractory 133 and the separate upper refractory 134 and then by flame It can also cause the adhesive to fly to carbon when heated.

However, this is not necessarily limited to the present invention and is a matter that can be appropriately modified and applied by those skilled in the art.

In addition, according to the present invention, it is possible to prevent the refractory is wasted, it is possible to reduce the landfill cost of the used refractory has the effect of reducing the associated costs.

Meanwhile, in order to use the fitting tolerance, the first diameter 134a of the split upper refractory 134 and the first diameter 133a of the upper refractory may be provided to have an intermediate fit or an interference fit tolerance. The same may be applied to the second diameter 134b of the separated upper refractory 134 and the second diameter 133b of the upper refractory 133.

By using these fitting tolerances to enable their coupling and separation can further reduce the time required to prepare the test, there is an effect that can minimize the cost required to manufacture the tester.

As such, a method of using a fitting tolerance, a surface friction, an adhesive, and the like may be equally applied to the lower refractory 131 and the separate lower refractory 132, but the separate lower refractory 132 may be applied to the lower refractory 131 by gravity. Since it is possible to maintain the state mounted on the bed, the test may be performed only by placing the removable lower refractory 132 on the lower refractory 131 as necessary.

In addition, abutting the fastening holes 141 provided in the tester body 110 and the tester cover 120, respectively, by inserting the fastening bolt 142 and inserting the nut 143, the tester body 110 and the tester cover ( 120 can be firmly combined. However, their combination can be replaced by any other means other than bolts and nuts.

5 illustrates a state in which the tester cover 120 is turned upside down, and referring to this, the detachable upper refractory 134 is an external inclined surface 134d contacting the internal inclined surface 133c of the upper refractory 133 and An internal inclined surface 134c, which is a surface facing the specimen (P in FIG. 6).

And the vertical distance from the outer inclined surface 134d to the inner inclined surface 134c of the detachable upper refractory 134 becomes thick. This thickness may be set in consideration of the amount of contaminants (not shown) generated by the reactants (not shown), the depth and shape to be fixed, and the like.

That is, the thickness is determined by the reaction material (not shown) and the flame (not shown) introduced into the flame inlet hole 121 of the tester cover 120 and the through hole 135 of the separate upper refractory 134 facing the flame inlet hole 121. A thickness such that the contaminants (not shown) formed do not reach the internal inclined surface 133c of the upper refractory 133 is suitable.

At this time, the center of the flame inlet hole 121 and the center of the through hole 135 may exist in the same line in the direction of gravity, the diameter of the flame inlet hole 121 is larger than the diameter of the through hole 135 Can have

6 is a refractory damage simulation tester 100 is completed by the fastening bolt 142 and the nut 143.

At this time, the sidewalls of the tester body 110 may be provided in the circumferential direction of the tester body 110 to protect the sidewalls of the tester body 110 to support the specimen (P).

And the lower surface of the specimen (P) is in contact with the removable lower refractory 132, whereby the lower portion of the specimen (P) can be supported. At this time, the specimen (P) is made of the same material and components as the refractory applied to the actual blast furnace, it may have a certain volume so as to be easily accommodated in the tester body (110).

The upper refractory 133 and the separate upper refractory 134 may contact the upper portion of the specimen (P). At this time, the first diameter 133a of the upper refractory and the first diameter 134a of the separate upper refractory 134 may be adjusted to control an area in contact with the refractory and the specimen P.

At this time, as shown in Figure 6, if both the upper refractory 133 and the separate upper refractory 134 is in contact with the specimen (P), the specimen (P) supports the lower portion of the removable upper refractory 134, the removable upper refractory 134 ) Is prevented from being separated from the upper refractory (133).

In this state, the reaction material (not shown) and the flame (not shown) are introduced into the flame inlet hole 121 provided in the tester cover 120 and the through hole 135 provided in the separate upper refractory 134 to perform the test. You can proceed.

After the reaction is completed after a certain time, as shown in (a) of FIG. 7, the contaminant 300 is buried or adhered to the inner surface of the detachable upper refractory 134.

Then, as shown in (b), the detachable upper refractory 134 on which the contaminants 300 are deposited is separated from the upper refractory 133, and thus the external inclined surface 134d of the removable upper refractory 134 and the internal inclined surface of the upper refractory 133. The contact of 133c can be released.

And, as shown in (c), by combining a new removable upper refractory 134 prepared in advance can be completed to replace the removable upper refractory.

Such a separate upper refractory can be produced by the apparatus 200 for manufacturing a refractory damage simulation tester shown in FIG.

As another aspect of the present invention, the first mold 210, the second mold 220 to form a gap 230 to be spaced apart by a predetermined distance to the outer periphery of the first mold 210 to manufacture the above-described removable upper refractory and Provided is a manufacturing apparatus 200 for a refractory damage simulation tester having a pedestal 240 provided below the first and second molds 210 and 220.

At this time, the gap 230 is filled with a filler may be subjected to the construction, drying, curing process and preferably the filler may be alumina (Al ₂ O ₃ ) but this is not necessarily limited by the present invention, by those skilled in the art It can be changed and applied properly.

In this case, the filling of the filler in the gap 230 may be prepared in advance, such as before the test is carried out in a simulated tester, several separate upper refractory may be manufactured in advance.

Since the gap 230 becomes the thickness of the separate upper refractory (134 of FIG. 7), the gap between the first mold 210 and the second mold 220 may be adjusted in consideration of this. In addition, the first and second molds 210 and 220 may be provided to be separated into a predetermined number as necessary. However, this is also not necessarily limited by the present invention and is a matter that can be appropriately changed and applied by those skilled in the art.

According to the present invention as shown in Figure 9, it is possible to manufacture a separate upper refractory 134. The split upper refractory 134 includes a first diameter 134a and a second diameter 134b that is smaller than the first diameter 134a, and the diameter is from the first diameter 134a to the second diameter 134b. This may have a linearly decreasing form.

In addition, a through hole 135 through which a flame and a reactant (not shown) may be introduced may be provided on the same plane as the second diameter 134b. At this time, the internal inclined surface 134c of the separate upper refractory 134 may be a surface facing the specimen (P of FIG. 6).

As such, when the external inclined surface 134d and the internal inclined surface 134c exist on the separate upper refractory 134, the separated upper refractory 134 slides with the upper refractory (133 of FIG. 7) to facilitate separation or combination thereof. It is effective.

The matters described above have been described with respect to an embodiment of the present invention, and the scope of the present invention is not limited thereto, and various modifications and variations can be made without departing from the technical spirit of the present invention described in the claims. It will be apparent to one of ordinary skill in the art.

1, P: Specimen 10: Refractory Tester
11: lower body 12: upper body
13: irregular shape refractory 14: bolt hole
15 bolt 16: flame hole
17, 150: support filler 18: upper hole
100: refractory damage simulation tester 110: tester body
120: tester cover 121: flame entry hole
130: protection unit 131: lower refractory
132: separate lower refractory 133: upper refractory
134: removable upper refractory 135: through hole
141: fastening hole 142: fastening bolt
210: first mold 220: second mold
230: clearance 240: pedestal
300: contaminants

Claims (9)

A tester body accommodating the specimen therein;
A tester cover coupled to the tester body;
A protection unit provided in the tester body and the tester cover to support the specimen and be separated by a predetermined thickness;
Fastening holes provided in the tester body and the tester cover, respectively; And
Including; fastening bolt is inserted into the fastening hole;
The protective unit,
An upper refractory provided inside the tester cover; And
And a separable upper refractory provided in the tester cover in the center direction of the tester cover inward from the upper refractory and separated from the upper refractory.
The removable upper refractory includes a through hole through which contaminants formed by reactants and flames are introduced,
The specimen is a refractory damage simulation tester existing outside the through hole during the test.
The method of claim 1,
The protective unit,
A lower refractory provided at the lower part of the tester body; And
A separate lower refractory provided on an upper portion of the lower refractory and separated from the lower refractory to contact the specimen;
Refractory damage simulation tester further comprising a.
The method of claim 2,
The tester cover,
Having a flame inlet hole;
The upper refractory is,
A through hole placed on the same line as the flame inlet hole in a gravity direction;
Refractory damage simulation tester comprising a.
The method of claim 3,
The separate upper refractory,
And the through hole is coupled to the through hole of the upper refractory so as to face the flame inlet hole, and is provided to increase in diameter as it moves away from the flame inlet hole.
The method of claim 4, wherein
The separate upper refractory,
Refractory damage simulation tester, characterized in that provided with a linear increase in diameter away from the flame inlet.
The method of claim 5,
The diameter of the outer circumference of the removable upper refractory and the diameter of the inner circumference of the upper refractory is a refractory damage simulation tester, characterized in that provided with an intermediate fit or interference fit tolerance.
delete To produce the split top refractory of the refractory damage simulation tester according to any one of claims 4 to 6,
A first mold having an outer surface corresponding to an inner surface of the removable upper refractory;
And a second mold spaced apart from the outer circumference of the first mold to form a gap with the first mold.
Apparatus for producing a refractory damage simulation tester is provided to produce the separated upper refractory by filling a filler in the gap.
The method of claim 8,
Apparatus for producing a refractory damage simulation tester, characterized in that the filler is alumina.

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