Rongsheng Refractory Archives - Global Refractory Brick Supplier & Factory-Rongsheng

Semi-dry pressing

During the semi-dry pressing process, the loose materials do not have enough moisture and must be subjected to greater pressure. With the help of pressure, the blank particles are redistributed. Under the action of mechanical bonding force, electrostatic attraction and friction, the blank particles are tightly combined, elastic deformation and brittle deformation occur, air is discharged, and the blank particles are combined into products with a certain size, shape and strength.

The degree of action of the above forces depends on the particle shape, the physical and chemical properties of the blank and the surface state of the particles. For particles with complex shapes, mechanical bonding force plays a major role. For particles with simple shapes, friction and static electricity cause the main effects.

Within a certain range when other process conditions are the same, the pressure increases during pressing, the porosity of the blank decreases, the density increases, and the strength increases accordingly.

The blanks and bricks of refractory materials are three-phase systems composed of solid matter, water (or other binders in other states) and air. During the entire pressing process, because the amount of phase and liquid phase does not change, the amount of air in the blank is compressed and reduced, and the volume of the compressed blank is also reduced accordingly.

Slurry injection molding method

Use powdered raw materials, select appropriate degumming agents (deflocculating agents) to evenly suspend them in the solution, adjust them into mud, pour them into a water-absorbent mold (generally a gypsum mold) to absorb water, and form a green body according to the shape of the model. This method is called slurry injection molding.

For materials that do not react with water, water is generally used as a suspension, and the moisture content of the mud is as high as 35~45%. For some materials that are easy to react with water, such as CaO, MgO, etc., organic matter can be used as a suspension, such as anhydrous alcohol. This method is suitable for the production of thin-walled hollow products. Such as thermocouple sleeves, high-temperature furnace tubes and crucibles. Various oxide products, from small to large pieces, have adopted this method.

For thin-walled hollow products, hollow casting is generally used. Inject mud into the model, and after a certain period of time, the raw materials are adsorbed on the model wall. When the specified thickness is absorbed, the internal mud is discharged. Dry to an appropriate degree and then demold, the gypsum mold can be used repeatedly. The mud used should have good fluidity, and the density is generally between 1.65~1.80g/cm2.

For the casting of thick and large products, solid casting is suitable. The mud used should be large, and the density should generally be above 1.8g/cm3. The thick mud has thixotropy, so it should be strongly mechanically stirred before casting to make it fluid. After casting, it can be solidified by standing for a period of time. Therefore, the plaster mold used does not need to have high water absorption.

Plastic molding method

The moisture content of the blank used in the plastic method is generally above 16%. The prefabricated blank is put into the mud extruder, extruded into mud strips, and then cut. Then the blank is made into a blank according to the required size, and the blank is pressed by a press to make the blank have the specified size and shape.

The moisture content of the blank is related to different raw materials and products. For plastic clay materials, the moisture content can be appropriately reduced to 10~15%. The critical pressure of the mud extruder is related to the moisture content of the blank.

The plastic molding method is mostly used to prepare large products. Depending on the molding operation, it can be formed by hand, semi-mechanical (such as clamping hammer) or machine pressing.

With the improvement of refractory process technology and the development of molding machinery and equipment, the application of plastic molding methods in the refractory industry has a tendency to decrease.

Vibration molding

When the material vibrates at a frequency of about 3,000 times per minute, the particles of the blank collide with each other, and dynamic friction replaces the static friction between the particles, and the blank becomes a fluid particle. Due to the energy input by the vibration, the particles have the ability to move in three dimensions inside the blank, so that the particles can be densely packed and filled in every corner of the model and the air can be squeezed out. Therefore, even under very small pressure, a high-density product can be obtained. When molding a variety of products, vibration molding can effectively replace heavy high-pressure brick presses. For example, crank lever brick presses and hydraulic presses can mold complex special-shaped and giant bricks that require manual molding or ramming molding, greatly improving labor productivity and reducing labor intensity. Vibration molding is also suitable for molding materials with a large difference in density and molding fragile brittle materials. Since the material particles are not destroyed during molding, it is suitable for molding easily hydrated materials, such as tar dolomite, tar magnesia, etc.

Hot Pressing

Refractory products made by sintering require a long calcination time, and the porosity is still as high as 10~25%. Ceramic materials and products prepared by sintering still have a true porosity of 3~5% even under ideal conditions. Non-oxide ceramic materials, such as carbides and nitrides, have even greater porosity.

It is difficult to make very dense products. This is because during the sintering process, the gas pressure in the pores increases, offsetting the role of the interface energy as a driving force. On the other hand, closed pores can only be filled by diffusion of substances inside the crystal, but internal diffusion is much slower than interface diffusion. If the sintering process is carried out to the final stage and the product reaches an ideal dense state, there are two methods:

One is to use vacuum sintering to avoid gas accumulation in the pores.
The other is to apply pressure during sintering to ensure sufficient driving force.

The latter is called hot pressing.

Compared with the common sintering method, the advantage of hot pressing is that it can obtain special products with very high density, and its density value can almost reach the theoretical value. Adjusting the hot pressing conditions can control the grain formation, and hot pressing at high temperature is conducive to the contact and diffusion between particles. Thus, the sintering temperature is reduced (compared with the common sintering method).

Hot Pressing Molding (Hot Pressing Grouting)

Hot pressing is one of the grouting methods and is a relatively new method for producing ceramic products and special refractory materials.

Hot pressing generally uses an organic binder as a dispersion medium and silicate mineral powder as a dispersed phase. At a certain temperature (70~85℃), it is prepared into a slurry and then molded into a metal model. This method is suitable for the production of small products with complex shapes and special requirements. It is also suitable for the production of materials with low plasticity, such as the molding of high-aluminum materials. Its semi-finished products have high mechanical strength and can be turned and drilled by machine tools. The plaster model and drying process can be omitted, the equipment is simple, and mechanization is easy to achieve.

Electric Melting Method

The refractory raw materials are melted in an electric arc furnace, and then the melt is poured into a refractory casting mold for casting. Because the fluidity of the fluid must be good, the general pouring temperature must be between 1900~2000℃. The casting generates a stable crystal phase during the solidification process and forms a fine crystalline structure. After pouring, the casting mouth should be removed, and the casting should be slowly cooled for several days to prevent cracks from appearing during cooling. The casting block is finally processed on the surface to become a product. The products formed by this method are mainly fused zirconium mullite bricks, chrome corundum bricks, and fused quartz bricks. It is mainly used to build the bottom of the glass tank kiln. Most of the raw materials for producing rebonded bricks are also produced by this method.

Isostatic Pressing

Isostatic pressing is a new forming technology developed later. This method mainly applies the Pascal principle to pressurize the liquid and evenly transfer its pressure to the powder through the rubber film, so it has the following characteristics.

Formability. The pressurization is non-directional, and a green body with uniform density can be obtained, and there will be no layer density phenomenon during other mechanical pressing. It is easy to press into products with complex shapes.
Sinterability. Since the green body has uniform density and shrinkage during firing is non-directional, it will not cause stress due to density difference and cause firing cracks. Due to the high density, the firing temperature is relatively reduced.

The main equipment consists of a high-pressure container and a high-pressure pump. During molding, the powdered material is placed in a rubber film or a plastic film, placed in an ultra-high-pressure container with a thick steel wall, and a high-pressure liquid is injected by a high-pressure pump. The working pressure is generally above 343MPa. This method only formed small products at the beginning, and has now developed to press large products.

SK30, SK32, SK34, SK36, SK38, and SK40 are relatively common foreign refractory brands, which are different from domestic refractory bricks. Among them, SK-30, SK-32, SK-34, and SK-35 represent clay bricks, and SK-36, SK-37, SK-38, and SK-40 refer to high alumina bricks.

Refractory bricks refer to shaped refractory products made of refractory raw materials, which can withstand high temperatures above 1580°C. The main raw material is refractory clay (bauxite) mixed with clinker (calcined and crushed clay), stirred, waked up, and pressed into shape by a strong machine. After drying, it is made by calcining at a high temperature of more than 1000 degrees.

SK32 clay brick, SK34 clay brick, SK36 high alumina brick, SK37 high alumina brick, SK38 refractory brick

High-temperature-resistant bricks are called refractory bricks. It is mixed with refractory clay into clinker (calcined and destroyed clay) and then stirred and pressed into shape. The finished product is obtained by calcining after drying. There are also silica and high alumina bricks. Can be divided into SK32, SK34, SK36, SK38, SK40 refractory bricks. Refractory bricks are mainly used for furnace lining, flue, chimneys, and other parts. According to its shape and size, it can be divided into two categories: standard shape and special shape. The specification of refractory bricks is 230 mm × 114 mm × 65 mm, and special-shaped refractory bricks can be customized according to customer needs. Refractory bricks can be divided into ordinary refractory bricks according to their refractory degree, and the refractory degree is 1580-1770 ℃. For high-grade refractory bricks, the refractory degree is 1770~2000℃. According to its chemical function, it can be divided into three types: acidic, alkaline, and neutral.

Refractory bricks SK30, SK32, SK34, and SK35 refer to clay bricks. AL2O3% (≥) 30%, 35%, 38%, 45%. It is made of refractory clay and its clinker through crushing, mixing, molding, drying, and drying. Belonging to weakly acidic refractory products, the acidity increases with the increase of SiO2 content. It has a certain corrosion resistance to acidity, but poor resistance to alkaline corrosion.

SK36, SK37, SK38, and SK40 refractory bricks refer to high-alumina bricks with alumina content of 55%, 65%, 70%, and 82%. High-alumina bauxite is selected as the main raw material, and soft raw clay is added as a binder. After molding, it is fired at a high temperature of about 1500°C. High-alumina bricks contain more than 48% Al2O3. Its refractoriness, load softening point, and refiring shortening are higher than clay bricks, and its resistance to rapid cooling and heat is worse than that of clay bricks. High alumina bricks belong to neutral refractory materials, and their slag resistance function increases with the increase of Al2O3 content.

Rongsheng High Alumina Bricks Manufacturer

Now, the standards/types of refractory bricks that are widely used abroad are SK32, SK34, SK36, SK38, and SK40 refractory bricks. Our factory makes customized special-shaped bricks, which can be processed and customized according to the shape of the equipment and drawings, and the delivery cycle is short.

Refractory bricks can be divided into three types according to their chemical functions: acidic, alkaline, and neutral. It is a shaped product in refractory materials. According to its refractoriness, it can be divided into three grades with a refractoriness of 1580-1770°C, a refractoriness of 1770-2000°C, and a refractoriness of more than 2000 degrees.

The size of SK30, SK32, SK34, SK35, SK36, SK37, SK38, and SK40 refractory bricks is divided into standard size and special-shaped size. The standard size of refractory bricks for Rongsheng refractory brick manufacturer is 230*114*65mm. The special-shaped size is different according to the location of use and the audit requirements of the kiln, and the size can be customized according to the drawing. Clay bricks are roughly divided into: clay bricks for coke ovens, clay bricks for blast furnaces, clay bricks for hot blast stoves, and clay bricks for glass kilns according to their used parts. According to the volume density, it can be divided into general clay bricks, low-porosity clay bricks (dense clay bricks), and low-creep refractory bricks.

The refractory bricks produced by The Rongsheng Refractory Manufacturer has the characteristics of wear resistance, corrosion resistance, spalling resistance, low creep, and good thermal shock stability. The operating life is 1.5 times that of general products. Used in blast furnaces, hot blast stoves, carbon roasters, carbon calciners, coke ovens, steel ladles, casting systems, boilers, cement kilns, glass kilns, and various kiln linings and thermal equipment, etc. It is suitable for metallurgy, machinery, building materials, casting, ceramics, electric power, petroleum, chemical industry, and other industries. Contact us to get prices and samples for free.