Patent Grant
10247478
The present invention relates to a monolithic refractory structure.
Priority is claimed on Japanese Patent Application No. 2013-014504, filed on Jan. 29, 2013, the content of which is incorporated herein by reference.
In various types of industrial furnaces and facilities used under a high temperature, such as ironworks, various types of refractories such as firebricks, monolithic refractories, ceramic fiber, and the like are constructed depending on the use environment or necessary functions. In recent years, among these, the use of monolithic refractories (castable and plastic refractories and the like) has increased due to an increase in the degree of freedom of construction and shape and an increase in quality.
Inside the monolithic refractory, a metal support material typically called an anchor or stud, processed to an L-shape, a V-shape, or a Y-shape is buried. An end portion of the metal support material is fixed to a shell or pipe which is a support body of the monolithic refractory. The metal support material has a role of preventing the monolithic refractory from being peeled off or separated from the support body such as the shell or pipe or suppressing the propagation of a crack that occurs in the monolithic refractory.
Specifically, as shown in
The monolithic refractory 3 which covers the support body 1 has a single layer structure or a multi-layer structure. There may be cases where a shaped refractory such as a ceramic fiber, a heat insulating board, or a heat insulating sheet is used together with the monolithic refractory 3. The support body 1 is a structure obtained by combining metallic or ceramic members and is a furnace shell, pipe, beam, post, or the like. For example, as the support body 1 used in an iron and steel process, a furnace shell of a heating furnace, a water-cooling pipe of a skid, an immersion tube for secondary refining, a gas suction lance, or the like may be employed.
After the metal support materials 2 are fixed to the support body 1 with predetermined intervals therebetween by welding or the like, a slurry-like monolithic refractory raw material is poured into a molding box having an arbitrary shape installed in the periphery of the support body 1. Thereafter, through a finishing process such as curing process and drying process, a monolithic refractory structure as shown in
In a general monolithic refractory structure described above, a metal support material is present in the vicinity of the operation surface of a monolithic refractory exposed to a high temperature. The metal support material has a higher coefficient of thermal expansion than that of the monolithic refractory. Therefore, cracks occur in the monolithic refractory due to the difference in the coefficient of thermal expansion between the metal support material and the monolithic refractory. In addition, heat is transferred to the furnace shell, the water-cooling pipe, or the like via the metal support material having a high thermal conductivity and thus high heat loss occurs. Furthermore, in a case where the metal support material is used over a long period of time under an oxidizing atmosphere, the strength of the metal support material is reduced due to the oxidation. As a result, the holding force of the monolithic refractory is reduced, and particularly, there is a problem in that the monolithic refractory becomes separated from the tip end of the metal support material.
During the construction of the monolithic refractory structure of an industrial furnace, thousands to tens of thousands or hundreds of thousands of metal support materials are used although the number of materials varies depending on the size or structure of the furnace. In the monolithic refractory after an operation under a high temperature, many cracks that are initiated from positions where the metal support materials are installed are present. When such cracks propagate and are connected to each other, a possibility of peeling or separation of the monolithic refractory is increased. Therefore, the amount of initiated cracks is one of the factors that determine the life-span of the monolithic refractory structure.
Hitherto, as a countermeasure to the problem, in order to ensure the expansion allowance of the metal support material, a method of forming a resin film on the surface of a metal support material or winding a plastic tape around the surface thereof and thereafter burying the metal support material in a monolithic refractory is generally employed. According to this method, the resin film or the plastic tape is burned down due to the temperature increase, and thus a space (that is, expansion allowance) is formed in the periphery of the metal support material buried in the monolithic refractory.
However, according to the countermeasure of forming the resin film on the surface of the metal support material or winding the plastic tape around the surface thereof, it is difficult to sufficiently suppress the occurrence of cracks even though effort and cost is consumed.
Here, hitherto, a technique of using a heat-resistant fiber rope formed of an inorganic fiber as a support material instead of the metal support material is suggested (refer to the following Patent Documents 1 to 3). In Patent Documents 1 and 2, a technique of supporting a monolithic refractory using a heat-resistant ceramic rope formed of a ceramic fiber is disclosed. In Patent Document 3, a technique of using a rope (support cord) formed of an inorganic fiber such as glass wool, rock wool, slag wool, asbestos, ceramic fiber, alumina fiber, or carbon fiber as a support material is disclosed.
The inorganic fiber is formed of an inorganic material like the monolithic refractory and has a low coefficient of thermal expansion and has a further low elastic modulus. Therefore, in a case where the heat-resistant fiber rope is buried in the monolithic refractory as the support material, cracks hardly occur in the monolithic refractory due to a small difference in the thermal expansion between the monolithic refractory and the heat-resistant fiber rope.
In general, while the thermal conductivity of SUS steel or heat-resistant cast steel used for the metal support material is about 15 W/mK to 50 W/mK, for example, the thermal conductivity of alumina fiber is about 0.1 W/mK to 0.2 W/mK. Therefore, heat is hardly transferred to the furnace shell, the water-cooling pipe, or the like via the heat-resistant fiber rope, and thus heat loss can be reduced.
In addition, for example, the ceramic fiber is primarily formed of oxides such as Al2O3 and SiO2. Therefore, even when the heat-resistant fiber rope formed of the ceramic fiber is used over a long period of time under a high temperature oxidizing atmosphere, deterioration due to the oxidation does not occur unlike the metal support material.
[Patent Document 1] Japanese Unexamined Patent Application, First Publication No. H09-143535
[Patent Document 2] Japanese Unexamined Patent Application, First Publication No. 2005-42967
[Patent Document 3] Japanese Unexamined Utility Model Application, First Publication No. H07-32493
As described above, most of the problems that occur due to the use of the metal support material can be solved by using the heat-resistant fiber rope formed of the inorganic fiber as the support material instead of the metal support material. However, as a result of verification by the inventors, it was determined that the bearing force of the monolithic refractory (a force needed to fix the monolithic refractory to the support body) varies depending on the state of the heat-resistant fiber rope in the monolithic refractory.
That is, there is a possibility that a sufficient bearing force for the monolithic refractory may not be obtained depending on the state of the heat-resistant fiber rope in the monolithic refractory and the monolithic refractory may become separated from the support body. However, in the related art described above, there is no suggestion for an optimal state of the heat-resistant fiber rope in the monolithic refractory by focusing on the bearing force of the monolithic refractory.
The present invention has been made taking the foregoing circumstances into consideration, and an object thereof is to solve problems (a reduction in the bearing force of a monolithic refractory) that occur when a heat-resistant fiber rope formed of an inorganic fiber is used as a support material for supporting the monolithic refractory.
In order to accomplish the object to solve the problems, the present invention employs the following measures.
(1) According to an aspect of the present invention, a monolithic refractory structure includes: a monolithic refractory; a support body which supports the monolithic refractory; and a heat-resistant fiber support material which is buried in the monolithic refractory in a state of being connected to a support surface of the support body, in which the heat-resistant fiber support material includes a heat-resistant fiber rope which is formed of an inorganic fiber and extends along an X-axis direction perpendicular to the support surface, and a ratio L1/L2 of an X-axis direction length L1 of the heat-resistant fiber rope to an X-axis direction length L2 of the monolithic refractory is 0.35 or more and 0.95 or less.
Here, the description “extends along an X-axis direction” includes not only extension of the heat-resistant fiber rope in parallel to the X-axis direction, but also meaning that extension of the heat-resistant fiber rope in a state of being inclined at a predetermined angle from the X-axis direction is allowed as long as the condition that L1/L2 is 0.35 or more and 0.95 or less is satisfied.
(2) In the monolithic refractory structure described in (1), the heat-resistant fiber rope may be formed of an inorganic fiber made of a material containing one type or two or more types of Al2O3, SiO2, Al2O3—SiO2, and Al2O3—SiO2—B2O3.
(3) In the monolithic refractory structure described in (1), the heat-resistant fiber rope may be hardened by a hardener.
(4) In the monolithic refractory structure described in (1), the heat-resistant fiber rope may be connected to the support body via an anchor provided on the support surface.
(5) In the monolithic refractory structure described in (1), the heat-resistant fiber support material may further include a connection member which connects the heat-resistant fiber rope to the support body, and the connection member may be fixed to the support surface of the support body.
(6) In the monolithic refractory structure described in (5), the connection member may be a metal ring having a hollow tube shape, the heat-resistant fiber rope may be inserted into and fixed to the metal ring, and a direction in which a load of the monolithic refractory is exerted on the heat-resistant fiber rope and a direction in which the heat-resistant fiber rope is pulled from the metal ring may be the same.
(7) In the monolithic refractory structure described in (5), the connection member may be a metal ring having a hollow tube shape, the heat-resistant fiber rope may be inserted into and fixed to the metal ring, and a direction in which a load of the monolithic refractory is exerted on the heat-resistant fiber rope and a direction in which the heat-resistant fiber rope is pulled from the metal ring may be different from each other.
(8) In the monolithic refractory structure described in (1), the heat-resistant fiber rope may include one or two or more annular portions.
(9) In the monolithic refractory structure described in (1), the heat-resistant fiber rope may include one or two or more knots.
(10) In the monolithic refractory structure described in (1), the monolithic refractory may be divided into a plurality of layers along the X-axis direction, and the heat-resistant fiber rope may have a single annular portion for each of the layers of the monolithic refractory.
In the above aspect, the ratio L1/L2 of the X-axis direction (the direction perpendicular to the support surface of the support body; in other words, the direction where load of the monolithic refractory acts on) length L1 of the heat-resistant fiber rope to the X-axis direction length L2 of the monolithic refractory is 0.35 or more and 0.95 or less.
By holding the state of the heat-resistant fiber rope in the monolithic refractory so as to satisfy the condition described above, a necessary bearing force for the monolithic refractory can be obtained. As a result, the monolithic refractory can be prevented from being separated from the support body.
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
The support body 1 is a structure that supports the monolithic refractory 3 and is obtained by combining metallic or ceramic members. The support body 1 and the monolithic refractory 3 are the same as those of an existing monolithic refractory structure shown in
A planar support surface 1a is provided on the surface of the support body 1. Hereinafter, as shown in
The pin 4 having an L-shape is installed on the support surface 1a. The pin 4 has a role as an anchor to connect the support body 1 and the heat-resistant fiber support material 5 to each other.
The heat-resistant fiber support material 5 is buried in the monolithic refractory 3 in a state of being connected to the support surface 1a provided in the support body 1. The heat-resistant fiber support material 5 is formed of an inorganic fiber and has a heat-resistant fiber rope 7 that extends along the direction perpendicular to the support surface 1a (the X-axis direction in the figure). The heat-resistant fiber rope 7 is connected to the support body 1 via the pin 4 installed on the support surface 1a. In addition, the pin 4 forms a portion of the support body 1 and is not a constituent element of the heat-resistant fiber support material 5.
In
It is preferable that the heat-resistant fiber rope 7 be formed of an inorganic fiber made of a material containing one type or two or more types of Al2O3, SiO2, Al2O3—SiO2, and Al2O3—SiO2—B2O3. The heat-resistant fiber rope 7 formed of the inorganic fiber made of such the material has heat resistance and strength to bear a high temperature of, for example, 600° C. or higher, and furthermore, 1000° C. or higher at which an increase in heat loss and a reduction in strength occur in an existing metal support material.
Particularly, an inorganic fiber made of Al2O3—SiO2 has excellent high temperature resistance and cost performance. Among the inorganic fibers made of Al2O3—SiO2, an inorganic fiber containing 72 mass % of Al2O3 and 28 mass % of SiO2 is relatively easily available and has excellent cost performance. In addition, an inorganic fiber containing 90 mass % of Al2O3 and 10 mass % of SiO2 has more excellent heat resistance.
By twisting a plurality of inorganic fibers, a yarn is obtained. Furthermore, by joining a plurality of yarns to be processed into a rope shape, the heat-resistant fiber rope 7 which is a primary portion of the heat-resistant fiber support material 5 according to this embodiment is obtained.
In addition, by using the inorganic fiber containing two or more types of Al2O3, SiO2, Al2O3—SiO2, and Al2O3—SiO2—B2O3 as described above, for example, the heat-resistant fiber rope 7 which has a multi-layer structure in which the core and the outer layer have different materials can be obtained.
In a case where the monolithic refractory structure is used under a low temperature, for example, the heat-resistant fiber rope 7 formed of an inorganic fiber (carbon fiber) made of carbon or an inorganic fiber made of Al2O3—SiO2—CaO, CaO—SiO2, or the like may be used.
The heat-resistant fiber rope 7 has a rope form braided by using the inorganic fiber. As the type of braiding, 8 strands braiding (cross rope), 16 strands braiding (braided rope), solid cord braiding (solid cord), or the like may be employed, and the type is not particularly limited. A hollow rope such as sleeve may also be used. However, the space in the rope is preferably as small as possible.
In order for the heat-resistant fiber rope 7 to ensure strength to function as the support material of the monolithic refractory 3, it is preferable that the heat-resistant fiber rope 7 be formed of long fibers having a fiber length of, for example, 100 m or longer. Even in a case where short fibers are used, the short fibers may be braided into a rope shape. However, the short fibers are only entangled and thus are easily pulled. Therefore, the short fibers do not accomplish the function as the support material. In a case where the long fibers are used, a necessary tensile strength for the support material can be adjusted by changing the rope diameter. In addition, long fiber indicates a fiber having a long fiber length on the order of meters or longer (typically, on the order of kilometers or longer) and is distinguished from short fiber having a fiber length of about 1 mm to 50 mm.
As shown in
As described above, as a result of verification by the inventors, it was determined that the bearing force of the monolithic refractory 3 (a force needed to fix the monolithic refractory to the support body) varies depending on the state of the heat-resistant fiber rope 7 in the monolithic refractory 3.
After the heat-resistant fiber rope 7 (the heat-resistant fiber support material 5) is fixed to the support body 1, a slurry-like raw material of the monolithic refractory 3 is poured into a molding box having an arbitrary shape installed in the periphery of the support body 1. Thereafter, through a finishing process such as curing process and drying process, the monolithic refractory structure according to this embodiment is obtained.
Here, as shown in
The inventors verified an effect of the ratio L1/L2 of the X-axis direction length L1 of the heat-resistant fiber rope 7 to the X-axis direction length L2 of the monolithic refractory 3 on the bearing force of the monolithic refractory 3. As a result, it was discovered that as shown in
The reasons are as follows. That is, in a case where the monolithic refractory structure according to this embodiment is used in an actual industrial furnace or facility, the X-axis direction (the direction perpendicular to the support surface 1a) becomes a direction in which the load of the monolithic refractory 3 is exerted. Since the bearing force of the monolithic refractory 3 is a force that bears the load, it is thought that when the heat-resistant fiber rope 7 is hung down and the X-axis direction length L1 of the heat-resistant fiber rope 7 is reduced, the bearing force that bears the load (that is, a force in a direction opposite to the load in the X-axis direction) is reduced.
In a case where the ratio L1/L2 of the X-axis direction length L1 of the heat-resistant fiber rope 7 to the X-axis direction length L2 of the monolithic refractory 3 is smaller than 0.35, a portion of the monolithic refractory 3 that is not supported by the heat-resistant fiber rope 7 is about ⅔ of the X-axis direction length L2 of the monolithic refractory 3, and thus there is a possibility that the portion that is not supported by the heat-resistant fiber rope 7 may be easily separated from the support body 1.
In a case where the ratio L1/L2 of the X-axis direction length L1 of the heat-resistant fiber rope 7 to the X-axis direction length L2 of the monolithic refractory 3 is greater than 0.95, the tip end of the heat-resistant fiber rope 7 (an end portion thereof on the opposite side to the support body 1) is too close to the operation surface of the monolithic refractory 3 (a surface thereof on the opposite side to the support body 1), and there is a possibility that the heat resistance of the heat-resistant fiber rope 7 may have a problem.
In addition, it was confirmed that as long as the condition (L1/L2 is 0.35 or more and 0.95 or less) is satisfied, even when the heat-resistant fiber rope 7 is inclined downward in the Z-axis direction (vertically downward) with respect to the X-axis direction, if the angle between the heat-resistant fiber rope 7 and the X-axis direction is 45° or less, there is no problem in practical use.
Therefore, by holding the state of the heat-resistant fiber rope 7 in the monolithic refractory 3 so as to satisfy the condition (L1/L2 is 0.35 or more and 0.95 or less) described above, a necessary bearing force for the monolithic refractory 3 can be obtained. As a result, the monolithic refractory 3 can be prevented from being separated from the support body 1.
In order to hold the state of the heat-resistant fiber rope 7 in the monolithic refractory 3 so that the condition (L1/L2 is 0.35 or more and 0.95 or less) is satisfied as described above, it is preferable that the heat-resistant fiber rope 7 which is hardened in advance by a hardener or the like be used. Accordingly, before the raw material of the monolithic refractory 3 is poured into the molding box, the heat-resistant fiber rope 7 can be prevented from being hung down due to its own weight.
As described above, a state in which the heat-resistant fiber rope 7 is hardened in advance by the hardener and the strength of the heat-resistant fiber rope 7 is exhibited at room temperature during the construction of the monolithic refractory structure according to this embodiment is preferable. Strength indicates a force that bears deformation such as hanging, curving, or bending of the heat-resistant fiber rope 7 due to its own weight during the construction. As the hardener, a resin such as a commercially available oil varnish which is volatilized in a temperature rising procedure may be employed. The heat-resistant fiber rope 7 may also be molded into an arbitrary shape by fixing the heat-resistant fiber rope 7 and hardening the heat-resistant fiber rope 7 using the hardener.
In addition, a phenolic resin or coal-tar pitch which is carbonized in a high temperature region and maintains strength, or phosphoric acid, phosphate, silicate, silica sol, alumina sol, or the like which forms a vitreous network in a high temperature region may also be used as the hardener.
The heat-resistant fiber rope 7 has many spaces in its structure and can contain a large amount of moisture. One of the factors that determine the quality accuracy of the monolithic refractory 3 is the amount of added moisture. However, in a case where the heat-resistant fiber rope 7 is used, for the above-described reason, moisture is absorbed by the heat-resistant fiber rope 7 and the fluidity of the monolithic refractory 3 disappears. The use of the hardener has an effect of burying the internal spaces of the heat-resistant fiber rope 7 and thus also has an effect of preventing moisture of the monolithic refractory 3 from being absorbed by the heat-resistant fiber rope 7. Therefore, by using the heat-resistant fiber rope 7 that is hardened by the hardener, the quality of the monolithic refractory 3 is also enhanced.
In addition, in the related art documents (Patent Documents 1 to 3) described above, holding the state of the heat-resistant fiber rope 7 in the monolithic refractory 3 so as to satisfy the above-described condition in order to obtain a necessary bearing force, or means for holding the state (burying the heat-resistant fiber rope 7 in the monolithic refractory 3 in a state of being hardened by the hardener or the like) is not disclosed. Therefore, it is difficult for those skilled in the art to discover the present invention based on the related art documents.
The heat-resistant fiber support material 5 may have only the heat-resistant fiber rope 7 (see
As shown in
Furthermore, as shown in
Particularly in a case where the heat-resistant fiber support material 5 is used for the ceiling wall, the load of the monolithic refractory 3 is always exerted on the heat-resistant fiber support material 5 (that is, the heat-resistant fiber rope 7). When the shape of the heat-resistant fiber rope 7 is linear, the load of the monolithic refractory 3 is beared by the frictional resistance of the heat-resistant fiber rope 7 against the monolithic refractory 3. Therefore, in this case, peeling of the monolithic refractory 3 off from the heat-resistant fiber rope 7 easily occurs. By providing the knot 6 in the heat-resistant fiber rope 7, the heat-resistant fiber rope 7 can receive the load with the knot 6. As a result, the bearing force of the monolithic refractory 3 is increased, and thus the monolithic refractory 3 can be prevented from peeling off from the support body 1.
In a case where the monolithic refractory structure according to this embodiment is applied to various types of industrial furnaces and facilities, there may be many cases where the heat-resistant fiber support material 5 is fixed to the support body 1 made of metal, such as a shell or a water-cooling pipe. In consideration of workability and adhesion strength to the shell, it is preferable that the heat-resistant fiber support material 5 include the heat-resistant fiber rope 7 and the connection member made of metal and the connection member be fixed to the support body 1 made of metal, such as a shell, by welding. In a state where one end portion or both end portions of the heat-resistant fiber rope 7 are nipped by the connection member made of a material capable of being fixed to the support body 1 by welding, the connection member is fixed to the support body 1, thereby attaching the heat-resistant fiber rope 7 to the support body 1.
For example, as shown in
In addition, as shown in
Even in the embodiment shown in
Otherwise, the connection member of the heat-resistant fiber support material 5 is not welded to the support body 1, and the connection member may be indirectly fixed to the support body 1 by using an additional fixing member. For example, as shown in
In the embodiment shown in
In contrast to this, in an embodiment shown in
In addition to the annular heat-resistant fiber rope 7 described above, as shown in
Moreover, as shown in
In addition, in
As described above, by using the heat-resistant fiber rope 7 having one annular portion for each of the layers of the monolithic refractory 3, even though the third annular portion 7c is cut due to deterioration or the like, the bearing force of the monolithic refractory 3 can be held by the first annular portion 7a and the second annular portion 7b which are normal.
In
The heat-resistant fiber support material 5 according to this embodiment may also be used together with another support material according to the related art. For example, in a case where a large load of the monolithic refractory 3 is applied to the support body such as a ceiling, a metal support material which obtains a relatively high bearing force, a hanger brick, or the like may also be used together with the heat-resistant fiber support material 5.
The heat-resistant fiber support material 5 according to this embodiment and the monolithic refractory structure using the same can be applied to points where the metal support material according to the related art and the monolithic refractory structure using the same are applied in various types of industrial furnaces and facilities. In addition, the heat-resistant fiber support material 5 according to this embodiment may be applied to substitute the total amount or a portion of a metal support material at a position where the metal support material is used hitherto. Particularly, in a case where the support body 1 or the support body is cooled by water-cooling or air-cooling, heat lost from the furnace body is reduced in the heat-resistant fiber support material 5 compared to the metal support material, and thus the heat-resistant fiber support material 5 is effective.
As an example of the facilities, a skid of a heating furnace for rolling a steel piece may be employed. A skid is a facility for supporting and transporting the steel piece in the heating furnace. The skid includes pipes made of metal and has a structure in which the insides of the pipes are water-cooled for the purpose of maintaining hot strength and the outer periphery thereof is coated with a refractory insulating material to suppress water-cooling loss. At this time, when the water-cooling pipes are not insulated, heat transferred from the heating furnace to cooling water is increased, and great heat loss occurs as a result.
As shown in
Hereinafter, heat-resistant fiber support materials and monolithic refractory structures according to Examples of the present invention will be described in detail. The present invention is not limited to the following Examples.
The heat-resistant fiber rope 7 having a diameter of 5 mm was formed by using long fibers having a composition of 72 mass % of Al2O3 and 28 mass % of SiO2 as an inorganic fiber. The tensile strength of the heat-resistant fiber rope 7 at room temperature was 50 MPa. The tensile strength of the heat-resistant fiber rope 7 after being baked at 1200° C. for 5 hours was 40 MPa.
As shown in
After operating the heating furnace at an operation temperature of 1350° C. for six months, the status of the constructed body of the monolithic refractory 3 was checked. It was confirmed that the heat-resistant fiber support material 5 could be used in an actual machine of the heating furnace without problems such as cracking.
Both end portions of the heat-resistant fiber rope 7 were inserted into the metal ring 8 which was made of SUS steel and had a height of 20 mm and an inner diameter of 10 mm to form an annular portion and were pressed to press the rope portion and the metal portion, thereby producing a heat-resistant fiber support material 5 having the form shown in
As shown in
In the same manner, as shown in
Furthermore, as shown in
At this time, the heights of all of the heat-resistant fiber support materials 5 of Invention Examples 1 to 3 and the metal support material 14 of Comparative Example 1 were 140 mm.
When the back surface temperature of the shell of the heating furnace during an operation is measured by a thermo viewer, while the back surface temperature of the shell was 130° C. in cases of Invention Examples 2 and 3 using the heat-resistant fiber support material 5, the back surface temperature of the shell was 160° C. in cases of Comparative Example 1 using the metal support material 14. Therefore, there was a temperature difference of about 30° C. between the back surface temperature of the shell of Invention Examples 2 and 3 and the back surface temperature of Comparative Example 1, and it could be confirmed that by using the heat-resistant fiber support material 5, heat loss could be reduced by about 30 percent in terms of heat dissipated from the shell.
When each of the monolithic refractory structures was observed after the operation of the heating furnace, in the cases of Invention Examples 2 and 3 in which the heat-resistant fiber support material 5 was used, no cracks on the operation surface (the surface of the monolithic refractory 3) were confirmed. However, in the cases of Comparative Example 1 in which the metal support material 14 was used, a crack occurred in the monolithic refractory 3 from a position where the support material 14 was installed as the origin and propagated in a cross shape. When a crack propagates by repeating heating and cooling, peeling and separation of the monolithic refractory 3 occur. However, it could be confirmed that when the heat-resistant fiber support material 5 was used, the life-span of the monolithic refractory 3 was enhanced.
In addition, the heat-resistant fiber support material 5 was recovered after being used in an actual machine for about one year, and the strength of the portion of the heat-resistant fiber rope 7 which was clamped by the metal ring 8 was measured in a tensile test. As a result, in Invention Example 2, the strength was reduced by about 20 percent from that before use, and in Invention Example 3, the strength was rarely deteriorated. Therefore, in the actual machine, long-term stability of the heat-resistant fiber support material 5 having the structure shown in
Both end portions of the heat-resistant fiber rope 7 were inserted into the metal ring 8 which was made of SUS steel and had a height of 20 mm and an inner diameter of 10 mm to form an annular portion and were pressed to press the rope portion and the metal portion, thereby producing a heat-resistant fiber support material 5 having the form shown in
As shown in
In addition, for comparison, the same construction was adopted by using the metal support material 14 (Y-shaped stud) which was made of SUS304 under the same conditions (Comparative Example 2).
At this time, the heights of both of the heat-resistant fiber support materials 5 of Invention Example 4 and the metal support material 14 of Comparative Example 2 were 80 mm.
The heating value of cooling water was calculated on the basis of the temperature difference between the inlet and the outlet of the cooling water in the water-cooling pipe 13 in the skid during the operation. In the case of Invention Example 4 in which the heat-resistant fiber support material 5 was used, compared to Comparative Example 2 in which the metal support material 14 was used, the heating value of the cooling water was reduced and the fuel unit consumption [Mcal/ton] was reduced by about ½. Here, the fuel unit consumption is an index that represents energy used per 1 ton of produced steel piece, and an increase in the fuel unit consumption means an increase in the heating value of the cooling water through the water-cooling pipe 13, that is, an increase in energy loss.
In addition, as in the case of Comparative Example 1, in Comparative Example 2 in which the metal support material 14 was used, a crack had occurred in the monolithic refractory 3 from the position where the support material 14 was installed as the origin. However, in Invention Example 4 in which the heat-resistant fiber support material 5 was used, no cracks on the operation surface (the surface of the monolithic refractory 3) were confirmed.
From the above-described results, it could be confirmed that the application of the present invention contributes to a reduction in cost, energy saving, and an increase in the life-span of the monolithic refractory structure by reducing heat loss energy.
While the exemplary embodiments of the present invention have been described in detail with reference to the accompanying drawings, the present invention is not limited to the examples. It is apparent that various modified examples and corrected examples can be made by those skilled in the art to which the present invention belongs without departing from the technical idea of the appended claims, and it is understood that these examples naturally belong to the technical scope of the present invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2013-014504 | Jan 2013 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2014/052010 | 1/29/2014 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2014/119632 | 8/7/2014 | WO | A |
| Number | Name | Date | Kind |
|---|---|---|---|
| 3766000 | Gibson | Oct 1973 | A |
| 3771467 | Sweet | Nov 1973 | A |
| 20100119425 | Palmer | May 2010 | A1 |
| 20110011051 | Wienke | Jan 2011 | A1 |
| Number | Date | Country |
|---|---|---|
| 202329167 | Jul 2012 | CN |
| 49-7125 | Jan 1974 | JP |
| 52-85906 | Jul 1977 | JP |
| 61-197497 | Dec 1986 | JP |
| 6-317385 | Nov 1994 | JP |
| 7-24961 | May 1995 | JP |
| 7-32493 | Jun 1995 | JP |
| 9-143535 | Jun 1997 | JP |
| 10-197161 | Jul 1998 | JP |
| 2001-201268 | Jul 2001 | JP |
| 2004-92983 | Mar 2004 | JP |
| 2005-042967 | Feb 2005 | JP |
| 2005-42967 | Feb 2005 | JP |
| 2005-55010 | Mar 2005 | JP |
| 2010-107091 | May 2010 | JP |
| 2013-76488 | Apr 2013 | JP |
| 5420878 | Feb 2014 | JP |
| Entry |
|---|
| Chinese Office Action and Search Report dated Mar. 23, 2016, for Chinese Application No. 201480006125.3 with the English translation of the Search Report. |
| International Search Report, issued in PCT/JP2014/052010 dated Apr. 22, 2014. |
| Office Action, issued in JP 2013-014504, dated Apr. 22, 2014. |
| Written Opinion of the International Searching Authority, issued in PCT/JP2014/052010, dated Apr. 22, 2014. |
| Korean Office Action, dated Sep. 9, 2016, for Korean Application No. 10-2015-7020704, together with an English translation thereof. |
| Number | Date | Country | |
|---|---|---|---|
| 20150362253 A1 | Dec 2015 | US |
