KR200300558Y1 - Heat protecting tube for molten metal probe - Google Patents

Abstract

The present invention relates to a thermocouple and sampler heat-resistant protective tube used in the temperature measurement, component measurement and sampling of molten metal in the steelmaking and steelmaking process, and the manufacturing method thereof.

The present invention is 20-90% inorganic powder as the main raw material; 5-50% of inorganic fiber as an auxiliary material; It consists of 3-15% of organic and inorganic binder as a binder, and is characterized by a heat-resistant protective tube for a molten metal probe having characteristics such as heat resistance, heat insulation, corrosion resistance, and molten metal scattering resistance.

According to the present invention, the heat protection tube for thermocouples, samplers and composite probes produced by the present invention is an inorganic powder whose main component is excellent in heat resistance and heat insulation, and is effective for improving erosion resistance. There is an advantage. In addition, since the branch pipe and the heat-resistant protective tube can be manufactured in one piece or separate type according to the shape of the probe, the manufacturing process is simple, and the effect of preventing corrosion and scattering of molten metal can be obtained.

Description

Heat-Proof Tube for Molten Metal Probe {HEAT PROTECTING TUBE FOR MOLTEN METAL PROBE}

The present invention relates to a heat-resistant protective tube for thermocouples, samplers, and composite probes used for temperature measurement, component measurement, and sampling of molten metal in steelmaking and steelmaking processes. To a heat-resistant protective tube for a molten metal probe manufactured by forming a slurry containing the powder on the outer circumferential surface of a core rod made of a paper tube or a light metal to improve heat resistance, heat insulation, corrosion resistance, splash resistance of molten metal, and the like. .

Generally, the temperature of molten iron or molten steel is about 1300 ~ 1800 ℃, so that the thermocouple, sampler, and composite probe are immersed in the molten metal for measurement of temperature, composition, and sampling. The use of a heat-resistant protective tube is essential to ensure a stable sampling condition and to ensure worker safety by splashing molten metal.

In order to exert the performance of the probe, it is preferable to use a material having excellent heat resistance, heat insulation, corrosion resistance, molten metal scattering resistance, and the like.

Conventionally, heat-resistant protective tubes are manufactured using asbestos (asbestos), a fibrous mineral, or ceramic fiber, an inorganic fiber, as a main component.

By the way, asbestos has the advantage of low manufacturing price, but is an environmental regulatory substance that causes cancer to the human body and has a disadvantage of being easily lost when immersed in molten metal due to its poor heat resistance and erosion resistance, and is an inorganic fiber ceramic Fiber is widely used as a substitute for asbestos due to its excellent heat resistance and heat insulation, but when immersed in molten metal, silica is eluted at 1200 ~ 1400 ℃ to contaminate the molten metal as well as bad corrosion resistance and especially high price of raw materials. It has been a factor in the rise of manufacturing prices.

In addition, when manufacturing probes for molten metal, regardless of the type of probe, the paper tube and the heat-resistant protective tube are separated and fabricated, and when assembled, they undergo a complex process of fixing staples to the paper tube and blocking both ends with cement. Due to the occurrence of cracks and the space between the branch pipe and the heat-resistant protective tube, and the cracks caused by thermal shock when immersed in the hot molten metal, the heat-resistant protective tube is burned out, which causes problems with stable temperature measurement and sound sampling of the probe. The complexity of the process has caused a problem of rising manufacturing costs.

The present invention was created to solve this problem in consideration of all the problems of the prior art as described above. And the slurry is extruded or press-molded on the outer circumferential surface of the core rod made of paper tubes or hard metals, and then dried sufficiently in hot air or at room temperature to manufacture a heat-resistant protective tube, which simplifies the work process and reduces the manufacturing cost of the probe. Of course, the object of the present invention is to provide a heat-resistant protective tube for molten metal probe which is excellent in heat resistance, heat insulation and corrosion resistance, and can prevent molten metal splash.

1 is an exemplary view showing a mounting state of the heat-resistant protective tube,

2 is an exemplary view showing a process of inserting and installing a heat-resistant protective tube using a metal core rod after insertion into the branch pipe.

Explanation of symbols on the main parts of the drawings

1 .... branch 2 .... heat-resistant protective tube

The above object of the present invention, 20 to 90% inorganic powder as the main raw material; 5-50% of inorganic fiber as an auxiliary material; It consists of 3 ~ 15% of organic or inorganic binder as a binder to provide heat-resistant protection tube for molten metal probe which is formed on the outer circumferential surface of the core rod made of paper tubes or hard metals with heat resistance, heat insulation, erosion resistance and splash resistance of molten metal. Is achieved by.

At this time, the inorganic powder is one or more selected from diatomaceous earth, talc, fly ash, characterized in that the particle size of 10 ~ 50㎛, and the inorganic fiber is any one selected from ceramic bulk fiber, rock wool, glass wool It is characterized by being cut to ~ 15mm, and characterized in that the organic binder of the binder is selected from carboxymethyl cellulose, methyl cellulose, polyvinyl alcohol and colloidal silica, alumina sol, sodium silicate as an inorganic binder.

Hereinafter, with reference to the accompanying drawings will be described in more detail the components added or limited use in the present invention and the reasons therefor.

1 is an exemplary view showing a mounting state of the heat-resistant protective tube, Figure 2 is an exemplary view of manufacturing by installing the heat-resistant protective tube using a metal core rod inserted into the branch pipe.

As shown, the heat-resistant protective tube (2) is provided in an integral form in close contact with the outer circumferential surface of the branch pipe (1) or by providing a heat-resistant protective tube (2) separately inserted into the branch pipe (1).

The heat-resistant protective tube (2) by extrusion molding the slurry mixture consisting of 20 ~ 90% of the main raw material inorganic powder, 5 ~ 50% of the inorganic fiber 5, 50% inorganic binder, 3 ~ 15% binder, on the outer peripheral surface of the branch pipe (1) Or press-molded and dried by hot air or normal temperature is formed.

Here, the shape of the heat-resistant protective tube 2 may have a variety of shapes, such as to cover a part or the whole of the branch pipe, and to form a spout in a part.

Inorganic powder, which is the main raw material, may be diatomaceous earth, talc, fly ash, and the like, and any one selected from these is preferably added 20 to 90%.

The reason why the amount of the inorganic powder added is limited is that when the amount of the inorganic powder is added less than 20%, the amount of inorganic fiber, which is an auxiliary material, is increased, so that the corrosion resistance is lowered, the thermal conductivity is increased, and the heat resistance and heat insulation are lowered. This is because there is a problem in that the moldability of the workability is lowered as well as the cracks during drying.

In addition, since the particle size of the inorganic powder has a deep relationship with the heat resistance, it is usually preferable to use a 10-50 μm particle, but an average 30 μm particle is used.

The diatomaceous earth is a collection of fossil soils in which the harmfulness of single-cell algae called diatoms is deposited on the seabed or the bottom, and its chemical composition is SiO ₂ 75.0-90.0%, Al ₂ O ₃ 4.0-9.5%, Fe ₂ O ₃ 1.0-2.5% It is known that the loss of ignition is 1 ~ 5%, the particle size is about 10 ~ 50㎛, the specific gravity is 2.05 ~ 2.15, and the volume porosity is 77 ~ 80%, which is 6 ~ 8 times that of general clay.

In addition, the thermal conductivity is 0.00013 ~ 0.00018gr.cal / cm ² / sec / ℃ at 100 ℃ ~ 900 ℃, and the specific heat is about 0.25, and it has various characteristics due to the porous material for use. It is widely used as a cement admixture and is also used in absorbents, degreasers, filtration aids, abrasives, insulations, filter media, and catalysts.

The talc is very soft, smooth to the touch, free from swelling by water or organic solution, little ion exchange ability, insoluble in acid, insulated against electricity, very soft and easily powdered, and absorbent, fastenable.

In addition, the crystal water is dehydrated and decomposed from about 850 ℃ to change to amorphous silica, which is often used as a powder raw material, and has a particle size of about 10 to 40㎛. Its uses include papermaking, rubber additives, plastic extenders, paints, Used for white pigments.

In particular, it is known to be widely used in electric magnetics such as high frequency heat transfer elements due to its characteristics such as resistance to thermal shock, high electrical resistance at high temperatures, and low dielectric loss.

The fly ash is a porous spherical particle that recovers the coal ash contained in the waste gas discharged during the high temperature combustion process of about 1400 ℃ by using pulverized coal as fuel in a combustion boiler such as a thermal power plant. The particle size is 1-100㎛. The chemical composition of SiO2, Al ₂ O ₃ , Fe ₂ O ₃ is about 75.0 ~ 90.0%, and it contains some CaO, MgO, loss of ignition. It is known to be used in various fillers, ceramic additives, and soil improving agents.

The inorganic fiber as a secondary material may be ceramic bulk fiber (CERAMIC FIBER), rock wool, glass wool (GLASS FIBER) and the like, and it is preferable to add any one selected from 5 to 50%.

As such, the reason for limiting the amount of the inorganic fiber added is less than 5%, and the amount of the inorganic powder, which is the main raw material, is increased, so that the impact is weak and cracks occur. The thermal conductivity is high and the manufacturing cost increases.

The ceramic bulk fiber (CERAMIC FIBER) is based on SiO ₂ 53.0%, Al ₂ O ₃ 47.0%, loss of ignition 6 ~ 10%, safe operating temperature is 1300 ℃, excellent heat resistance, very low thermal conductivity It has the advantage of low heat storage, light weight, and especially low thermal density and mechanical strength when added to thermal insulation materials. Its main uses include various insulation materials, ceramic fillers and heat reinforcing agents, composite materials and asbestos ( As a substitute for asbestos).

The rock wool is one of mineral fibers and the chemical composition is composed of SiO ₂ 35.0 ~ 45.0%, Al ₂ O ₃ 10.0 ~ 20.0%, CaO 20.0 ~ 40.0 MgO 3.0 ~ 10.0 Fe ₂ O ₃ 0.0 ~ 12.0% As it is excellent in heat insulation, sound absorption, fire resistance, and harmless to human body, it is widely used as an alternative material with increasing usage limit of asbestos (asbestos).

The glass wool (GLASS WOOL) also acts similar to rock wool, it is preferable to cut these inorganic fibers into 5 ~ 15mm added to the main raw material.

The binder is used to facilitate the bonding of the inorganic powder, the main raw material, and the inorganic fiber, and to maintain the strength at room temperature and high temperature. The binder is classified into an organic binder and an inorganic binder, and it is preferable to add 3-15% of those selected from them. Do.

The reason why the binder is added in this manner is less than 3%, so that the binding force is insufficient and corrosion resistance is reduced. When the binder is more than 15%, carbon dioxide is generated by reaction with the molten metal to promote the splash of the molten metal. This is because it has a disadvantage.

Examples of the organic binder include carboxymethyl cellulose (CMC), methyl cellulose (MC), polyvinyl alcohol (PVA), and the like. The inorganic binder includes colloidal silica (silica sol), alumina sol, and sodium silicate.

As described above, a slurry is formed by sufficiently stirring to add a uniform amount of water to the mixture of the inorganic powder as the main raw material, the inorganic fiber as the sub raw material, and the binder to form a uniform composition, and the slurry is extruded into the branch pipe 1 or the metal core rod. The heat protection tube 2 for molten metal probe can be manufactured by shaping | molding or press molding.

Looking at the molding method is as follows.

In the case of the extrusion molding method, the inorganic fiber as the main raw material is added to the inorganic fiber as a subsidiary material, and the binder and water are added thereto, followed by stirring so that the mixture is sufficiently mixed to form a slurry, and then the hollow pipe or the metal core can be formed in the hollow part. It is inserted into the tip of the extruder drill machine with a cylindrical nozzle and applied pressure to apply the slurry to the outer circumferential surface of the paper tube or metal mandrel and take it out.

At this time, in order to minimize the bubbles of the slurry and to increase the adhesion to the paper tube, by installing a vacuum pump in the extruder to maintain the vacuum by uniform mixing of the slurry applied to the outer peripheral surface of the paper tube to increase the adhesion to the paper tube There is also a way.

In the case of the press molding method, the slurry mixed with the main raw material, the sub raw material, and the binder together with water is mixed with water, and the branch pipe is inserted into the mold of the press with the split-type mold having the heat-resistant protective tube, and the slurry is introduced and pressurized. A uniform heat-resistant protective tube is prepared so that the slurry adheres well to the outer circumferential surface and there are no bubbles therein, and the outer circumferential surface of the branch pipe is preferably manufactured to have a rough surface so that the slurry can be adhered well.

As described above, the heat-resistant protective tube manufactured by extrusion molding or press molding is dried in a hot air drying furnace maintained at about 60 ° C. for at least 6 hours or sufficiently dried at room temperature for at least 24 hours to completely remove moisture.

At this time, it is preferable that the moisture content of the heat-resistant protective tube is maintained at about 10%.

In addition, the reason for limiting the drying temperature and drying time as described above is that when the molded product containing moisture is dried at 60 ° C. or more, it shrinks with evaporation of moisture, and cracks are easily generated and the size of the product is changed. Therefore, it is preferable to dry naturally at room temperature or dry without rapid temperature change in the range of about 60 ℃, and drying the drying time for more than 6 hours in hot air or sufficiently drying for more than 24 hours at room temperature is the moisture content of the heat protection tube after drying. To keep cracks at less than 10% and to minimize corrosion and at the same time to secure erosion resistance. If moisture is contained at 10% or more, splashing of molten metal occurs due to carbonization reaction by reaction when immersed in molten metal. Because it causes.

Hereinafter, an embodiment of a heat resistant protective tube according to the present invention will be described.

EXAMPLE

The heat-resistant protective tube constituents of the present invention were prepared through the four kinds of blending examples as described below, and through the above-described process, the inventive materials 1,2,3,4 were prepared, and extrusion molding was used.

The compounding examples of these devises are described below, and the test results for the properties and properties between the devises and the existing materials are shown in Table 1.

ㅇ Formulation Example 1

-. Diatomaceous earth: 60.0%

-. Ceramic Bulk Fiber: 30.0%

-. Sodium Silicate: 5.0%

-. Carboxy Metal Cellulose: 3.0%

-. Colloidal silica: 2.0%

ㅇ Example 2

-. Diatomaceous earth: 70.0%

-. Ceramic Bulk Fiber: 20.0%

-. Sodium Silicate: 5.0%

-. Carboxy Metal Cellulose: 3.0%

-. Colloidal silica: 2.0%

ㅇ Example 3

-. Talc: 60.0%

-. Ceramic Bulk Fiber: 30.0%

-. Sodium Silicate: 5.0%

-. Carboxy Metal Cellulose: 3.0%

-. Colloidal silica: 2.0%

ㅇ Example 4

-. Fly Ash: 60.0%

-. Ceramic Bulk Fiber: 30.0%

-. Sodium Silicate: 5.0%

-. Carboxy Metal Cellulose: 3.0%

-. Colloidal silica: 2.0%

Table 1 below shows the results of making a thermocouple for molten metal through the design material and the existing material, and the results of the direct experiment. After maintenance, the surface was visually inspected to determine whether cracks caused by thermal shock occurred on the surface of the heat-resistant protection tube. In the case of erosion resistance, it was confirmed by melting traces on the surface of the heat-resistant protection tube. After immersing in molten metal, the temperature was measured according to the degree of scattering of molten metal during the measurement of temperature. It was.

number division Characteristics Comparison Remarks Heat resistance Corrosion resistance Shatterproof Temperature waveform One Devising Materials1 ◎ ◎ ◎ ◎ 2 Design Material 2 ◎ ◎ ◎ ◎ 3 Design Material 3 △ △ △ △ 4 Design Material 4 ◎ △ ◎ ◎ 5 Existing Material △ △ △ △

Note) ◎: Superior, △: Normal, X: Inferior

As shown in Table 1, the devised materials 1, 2, and 4 produced by the present invention showed superior properties compared to the existing materials in the stability of erosion resistance, heat resistance, anti-scattering and temperature waveforms. Has almost the same level of physical properties as existing materials.

As described in detail above, the thermocouples, samplers, and composite probe heat-resistant protective tubes manufactured by the present invention are inorganic powders whose main components are excellent in heat resistance and thermal insulation, and have an effect of improving erosion resistance, and are harmless to the human body and have high manufacturing cost. It has the advantage of less. In addition, since the branch pipe and the heat-resistant protective pipe can be manufactured in one piece or separate type according to the shape of the probe, the manufacturing process is simple, and the effect of further preventing corrosion and splash of molten metal can be obtained.

Claims (4)

20 ~ 90% of inorganic powder as main raw material; 5-50% of inorganic fiber as an auxiliary material; Binders of organic and inorganic binders 3-15%; And Heat-resistant protective tube for molten metal probe made of the remaining water and is formed on the outer peripheral surface of the branch pipe having heat resistance, heat insulation, corrosion resistance, molten metal scattering prevention. The method of claim 1, The inorganic powder is any one selected from diatomaceous earth, talc, fly ash, the heat-resistant protective tube for a molten metal probe, characterized in that the particle size of 10 ~ 50㎛. The method of claim 1, The inorganic fiber is a heat-resistant protective tube for a molten metal probe, characterized in that cut to 5 ~ 15mm as any one or a combination of ceramic bulk fiber, rock wool, glass surface. The method of claim 1, The binder is carboxymethyl cellulose, metal cellulose, polyvinyl alcohol as an organic binder, and colloidal silica, alumina sol, sodium silicate is optionally added as an inorganic binder.