Causes and Preventive Measures of Steel Leakage in Continuous Casting Machine

Steel leakage

One of the main operational faults encountered in continuous casting is "steel leakage". When the shell of the casting billet breaks down, the static molten steel in the shell overflows and blocks the machine, which requires expensive shutdown costs. In order to pull out the billet shell, the stop time caused by the steel leakage should be extended, because it may block the guide roller or foot roller. It needs to be cleaned and blocked by gas cutting and pulled out the blank shell. 

When the missing billet shell temperature decreases, it needs to be cut into small pieces and taken out of the machine by a straightener. The straightener is designed to straighten the curved cold billet shell gradually in a stable stage. The upper roller can provide enough lifting gravity to make the bending casting flow not too long. Therefore, the steel leakage has a significant impact on the effectiveness of the continuous caster - affecting productivity and production cost.

Influencing factors of steel leakage:

1. Temperature and pulling speed are not consistent.

The higher the superheat of molten steel, the thinner the thickness of the shell. Due to the static pressure exerted by the molten steel in the mould, the shell of the billet expands. When the strength of the shell is not enough, it is easy to leak steel. The inconsistent and uneven temperature has a great influence on the steel leakage. When the pulling speed increases, it is easy to leak steel, because the mould is not lubricated enough, and the fluidity of mould protection slag is poor from the meniscus to the shell/mould wall, and the increase of the pulling speed will lead to the decrease of total heat release. 

The steel leakage is often caused by too high pulling speed. When the billet shell does not have enough time to solidify to the required thickness, or the metal is too hot, this means that the final solidification happens just under the straightening roller. Due to the stress applied during straightening, the shell is torn. When the carbon content of steel is certain, the steel leakage is easy to occur when the temperature is high and the pulling speed is fast. Any change in the vibration setting will cause steel leakage, because the way of reducing the vibration mark by increasing the vibration frequency will increase the moulding rate and increase the friction at the interface.

2. Poor lubrication between mould and billet shell 

If the poor quality protection slag is used, the steel under the meniscus is easy to contain slag, which leads to the bond between the mould and the shell, and the blank drawing is interrupted, and the suspension steel leakage is caused. During continuous casting, due to poor lubrication or uneven lubrication, the shell of the billet is bonded to the mould, which affects the heat transfer, resulting in bonding and steel leakage.

3. The method of adding the protective slag is incorrect 

Because of the working habits of the workers on-site, too much is added at one time, and the main arc is concentrated in the arc, which is the slope, which will cause uneven filling of liquid slag, which will affect the lubrication and uniform heat transfer between the mould and the shell. Under normal pouring conditions, it is unnecessary to remove the small slag strip. It is forbidden to use the slag bar to test whether the slag strip is formed in the mould, which will damage the uniform formation of the initial shell of the meniscus.

4. Ineffective flow in the mould 

Reducing the flow into the mold will lead to a reduction of heat transfer, resulting in the formation of a thin shell, and eventually steel leakage. The temperature, pressure and flow rate of the inlet and outlet directly affect the cooling of the crystallizer. The pressure increases and the flow rate decreases due to the blockage of the cooling system of the crystallizer, which affects the heat transfer and easily causes steel leakage. Therefore, the great difference of water temperature (high temperature) at the inlet and outlet leads to the bond between the mould and the shell, and the steel leakage is easy to be broken.

5. Improper mould geometry 

In order to increase the contact surface of molten steel mould and adjust the taper of the mould to adapt to the solidification shrinkage of steel, thus increasing the heat transfer of the mould and increasing the thickness of the shell. For the traditional mould with linear taper on a high-speed billet continuous caster, the heat transfer at the meniscus makes the casting flow solidify into a solid shell rapidly. With the shrinkage of the shell, the corner is separated from the mould and the heat transfer stops. Therefore, at the bottom of the mould, the shell continues to grow except for the remelting of the corner. When the shell leaves the mould, the temperature of the shell changes greatly, and the increase of the pulling speed may lead to steel leakage. If the taper is not satisfied, an air gap will be generated between the mould and the shell. When the resistance of air to heat transfer in the mould reaches the maximum, it will seriously hinder the formation of the required thickness of the shell, and eventually lead to steel leakage. The taper loss of mould caused by wear and deformation will result in a significant increase in the longitudinal crack of the corner, which is due to the reheating of the corner. 

As far as the mould deformation is concerned, the reason is that the thickness of the copper plate is thin, which is not enough to support the thermal expansion of the copper plate. It may also be that when the ingot bar is inserted into the mould, the lower part of the mould will be damaged and the mould will be deformed. The taper of the mould increases the drag of the blank drawing, which leads to the increase of mould wear. The thickness of the air gap increases with the increase of taper and heat shrinkage, and then the wear of the large corner is added. Therefore, the heat transfer which causes the surface temperature to rise should be reduced. This phenomenon always accompanies the hydrostatic pressure of steel, which will induce tensile strain on the corner surface, which leads to cracks. This kind of crack will reduce the thickness of the shell by fixing, which may lead to steel leakage. The larger the radius of the mould fillet, the larger the air gap. The air gap hinders the heat transfer, which leads to the formation of thin billet shell, which is easy to leak steel. In slab/bloom caster, four separate copper plates are fixed to form holes around them. If there is air gap between the two copper plates, the initial metal will penetrate the air gap and start to solidify, and cause suspension in the later stage, leading to steel leakage. Therefore, improper adjustment of the crystallizer will affect the heat transfer mechanism and cause steel leakage.

6. The steel level in the mould is not suitable 

During continuous casting, the steel level in the mould should be maintained at 70% - 80% of the mould height. If the steel level falls below the immersion nozzle, the solidified shell formed by the subsequent addition of molten steel is thinner and easy to leak. Steel level drop may occur during the plugging of the water inlet, tundish or tundish. When the molten steel is restricted from the tundish to the mould, if the pulling speed is not adjusted, the steel leakage may occur. Therefore, if the control of plug rod is not suitable, the rotation causes the steel overflow, and the sticking to the top of the mould will cause suspension and block drawing, and lead to steel leakage. The decrease of steel level will also cause slag inclusion. If there is sufficient time for the plug bar to close the immersion nozzle, the steel level can be reduced to below the allowable limit. If the pouring starts again, the molten steel will inhibit the mold protection slag, resulting in slag inclusion. 

Therefore, when the ladle is completely cast, the steel level of tundish will drop. If the operation is not correct, the slag can enter the steel water in the mould through the immersion nozzle. The oxidation products of steel flow, improper deoxidation products, and high viscosity slag formed by the high Al2O3 caused by improper spraying of aluminium wire in billet mould may infiltrate into the shell to form slag inclusion, locally inhibit the formation of billet shell, reduce the lubrication between the shell and the mould, and easily bond, which will lead to the interruption of drawing billet and steel leakage. For the automatic control system of the diameter nozzle, the instability of the molten steel level in the mould will cause the fluctuation of the pulling speed, which will affect the stable filling of the slag into the mould and the shell, destroy the continuity of the slag film, and easily make the thickness of the shell uneven, and cause the surface depression or corner crack and steel leakage. The liquid level fluctuates greatly when replacing the immersion nozzle in production, and it also easily causes corner crack or slag leakage.

7. Eccentric pouring flow in the tundish 

The eccentric pouring flow of tundish leads to uneven heat transfer, uneven thickness of solidified shell, decrease of strength at the weak part of billet shell, and it is difficult to bear static pressure of molten steel, so steel leakage is caused. The misalignment of immersion nozzle, the center of steel flow is slanted, the local erosion of billet shell is serious, the uniformity of cooling of the shell in the mould will be greatly affected, and the steel leakage will also be caused when it is serious. The tundish shell is easy to deform locally for a long time, which causes the water inlet to be out of alignment or the insertion depth is not uniform; Improper installation of upper water inlet and block during repair and tundish will also cause the misalignment of immersion nozzle. In production, the center of the nozzle can be judged by comparing the vibration mark depth of the surface of the billet shell.

8. The air mist cooling nozzle is blocked 

The foot roller area is located under the mould, and the water is directly sprayed on the shell through the nozzle. The blank shell is under the pressure of the roller, making the shell smoother. At this time, the heat transfer is the largest, which is convenient to form a thicker shell. If the nozzle is blocked, the thickness of the shell will become thinner, which will easily cause steel leakage. In case of blockage, external force shall be applied by pulling roller. If the limit is exceeded, the surface of the shell will be broken and steel leakage will be caused.

9. Ingot bar irregularity 

Once the molten steel solidifies above the ingot bar of the mould, forming a blank shell of sufficient thickness, the ingot bar will be pulled out slowly. If the ingot bar is not pulled out according to the rules, steel leakage will easily occur. Similarly, the poor assembly of the dummy bar will cause the molten steel to flow out of the mould, leading to steel leakage. If the ingot bar is separated from the shell before the head of the dummy bar is lifted, it will lead to steel leakage.


According to the appearance of the shell, the steel leakage is divided into the following categories:

10. Suspension or bonding causes steel leakage 

The water of steel is bonded to the mould, and therefore is called bonding or hanging. This may be caused by improper lubrication between the mould and the shell or improper adjustment of the mould. The improper lubrication may be caused by the poor quality of the protection slag, slag inclusion in the shell of the mould, overflow of the molten steel of the mould, corner joint of the mould, and poor/unequal operation of the billet caster.

11. The cracks cause the steel leakage 

Longitudinal crack at the corner of the shell and the longitudinal crack in the wide plane will cause steel leakage. If longitudinal crack causes steel leakage, the flow of the slag is uneven, the uneven heat transfer of the mould results in the uneven thickness of the shell, improper selection of the protection slag and uneven cooling of the mould causes the shell rupture during cooling. For the steel leakage caused by a diagonal longitudinal crack, the shell with insufficient solidification thickness along the narrow surface of the mould breaks due to the tensile stress when it contracts. The tensile stress is caused by the decrease of taper of the narrow surface and uneven heat transfer on the narrow surface of the mould.

12. Slag inclusion and steel leakage 

The heat transfer is reduced due to the inclusion of protective slag or large particle inclusions in the shell, which leads to the formation of a thin shell and steel leakage. During billet continuous casting, secondary oxidation products, improper deoxidation products in high viscosity slag during low carbon steel smelting, improper injection of aluminium wire in the mould cause high Al2O3, which all promote slag inclusion in the shell, inhibit the growth of billet shell and cause steel leakage.

13. Thin shell steel leakage 

The observation of such steel leakage in billet caster is caused by uneven thickness of billet shell in the mould, which may be caused by eccentric casting flow in the mold or serious deformation of cooling pipe of mould.

14. Stop pouring causes steel leakage 

The continuous casting process breaks and fails to break the stop pouring. If the joint point cannot bear the pull force imposed by the recasting, the whole furnace steel will leak.

The measures to control the steel leakage should take necessary measures to control the occurrence of the steel leakage, considering the influence of the steel leakage on the utilization and effectiveness of the continuous casting machine.

● Only temperature measurement shall be conducted after argon blowing on the pouring platform to ensure the uniformity of temperature.

According to the chemical composition of steel, the pouring flow temperature must be kept over temperature of about 60 ℃ to place the ladle on the rotary table to ensure that the molten steel overheated 25-35 ℃ in the tundish.

● Control the speed of pulling according to the temperature monitored in the ladle. 

The carbon content in steel is fixed one by one to ensure that the temperature increases with the decrease of the pulling speed and the pulling speed increase with the decrease of temperature. Therefore, the pulling speed should be adjusted correctly according to the temperature and carbon content of the steel. The speed of the continuous casting is increased gradually, and the steady continuous casting is maintained by a certain pulling speed. Any interruption in continuous casting should reduce the speed of pulling.

● Any protective slag has a valid period, so it should not be used after the expiration date. 

The protective slag can only be opened during casting and dried under a high wattage bulb. The protective slag of the open bag shall not be used in casting again. Select the appropriate protective slag according to the specified chemical composition of the steel. At the beginning of casting, initial protective slag with low viscosity and low melting point shall be used. For billet caster, it is necessary to ensure that linseed oil is distributed evenly in mould.

● For slab/bloom caster, measure the thickness of slag pool to determine whether the thickness of slag pool is more than 10 mm and the equipment stroke composed of steel, copper and aluminium wires attached to the steel plate, which helps to avoid uniform lubrication of slag inclusion and shell.

● For a high-speed billet caster, various taper crystallizers can be used instead of traditional linear taper crystallizers. To check the mould deformation (if any). The taper of the mould is selected and the taper is adjusted according to the steel rhyme grade and the solidification mode of the mould on the slab/bloom caster to adapt to the narrow surface.

● Before the continuous casting, check the water flow in the mould and find out the blockage (if any) by measuring the increase of water pressure.

In general, check the difference of water temperature, pressure and flow at the inlet and outlet, and flow equipment. The water quality should also be checked. According to the grade of steel and its solidification mode, the cooling mode of mould, i.e. water flow rate (1 / min), is adjusted to adapt to various mould surfaces. In order to control the bonding, the thermocouple was used to detect the change of mould wall temperature and reduce the pulling speed to make the shell grow evenly. For a given caster, ensure that the inlet and outlet water temperature difference cannot exceed the specified value during continuous casting.

● Ensure that the maximum radius of the fillet along the copper plate is 0.2mm. 

If corner joints exist at the copper plate joints, the corner joints shall be filled with gypsum or lime before continuous casting.

● Install the mould level automatic controller on the continuous casting machine to keep the steel level of the mould. 

In order to distinguish the molten steel and slag in the mould and check the slag inclusion, the electromagnetic sensor is installed on the mould.

● Before casting, adjust the tundish nozzle and carry out alignment. 

Before the tundish water inlet is blocked, before the ladle is placed on the rotary table, it is necessary to ensure that the wire of Ca Si core is injected into the steel, which meets the requirements of high aluminium steel, so as to form low melting point calcium aluminate. Use a cryostat to avoid the rod from turning.

● By using metal protective flux in tundish and shielding plate between ladle and tundish, it is necessary to ensure that deoxidation products are appropriate to prevent the formation of secondary oxidation products. Mn / Si > 3 shall be maintained for the billet caster.

● Seal the spindle rod head with asbestos rope and use the quench box to ensure the correct distribution of the quench box before casting.

● To check the blockage (if any), check the spray cooling nozzle and water flow.

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Preventive Measures for Induction Furnace Leakage and Wear Accidents

The working temperature of the molten metal core of the induction melting furnace can reach up to 1600°C, which is high-risk equipment. Once the equipment, especially the steel shell furnace body, fails, it may cause major accidents. Therefore, it is of great significance to do a good job in the maintenance of the induction furnace from the details, and to understand the basic safety protection knowledge of the foundry melting furnace.

The common accidents of the furnace body of the crucible induction furnace include furnace leakage and furnace wear. If an accident occurs, if no measures are taken, it will cause the copper tube of the coil to rupture, the molten iron and the coolant will explode, which will cause major equipment accidents or personal injuries. Therefore, it is very important to clarify the cause of the accident, preventive measures and emergency measures after the accident.

1. Reasons for furnace leakage and furnace wear accidents

(1) The molten iron cools for too long and the lid is formed. It expands when heated again, and the lining is extruded to cause cracks in the lining. During the melting process, the molten iron penetrates through the cracks, causing the furnace to be worn or sprayed from the lid, causing a furnace injection accident.

(2) As the furnace age increases, the volume of the furnace lining becomes larger, the amount of molten iron in the furnace increases, the furnace lining is thinner, and the furnace cannot withstand the pressure of the molten iron locally, causing the furnace to wear.

(3) When the furnace lining is knotted, it partially fails to meet the requirements or partially brings in impurities and is not found, causing the above-mentioned defects to be penetrated during smelting.

(4) The rapid cooling of the furnace lining produces cracks, which penetrate through the cracks during the smelting process.

2. Preventive measures

(1) From the beginning of the furnace construction, a dedicated person must be strictly managed to ensure that the knots of each furnace lining are consistent. It is forbidden for sundries to fall into the furnace lining when knotting.

(2) Before each feeding, observe whether there are cracks in the furnace lining, perforation, etc., which may cause the furnace to penetrate. Once there is a problem, it must be dealt with.

(3) During the smelting process, due to equipment failure or other factors, the furnace cannot be opened for smelting for a long time, the molten iron should be turned out of the furnace to prevent cap formation.

During the smelting process, if the furnace body of the induction furnace has a furnace leak, it will cause heavy losses. Not only the entire furnace steel (iron) water will be scrapped, but the heart (inductor) of the furnace body will also be burned or even scrapped, and personal accidents may also occur. Therefore, in order to avoid unnecessary losses and affect production, it is very important to avoid furnace leakage when using induction melting furnaces. Generally speaking, the device leakage detection and alarm device is a necessary measure to ensure the safe operation of inductotherm induction furnaces and avoid the expansion of the incident.

Now, there is a way to install a stainless steel sheet (or disposable stainless steel wire mesh) on the inner side of the induction coil as the second electrode. The claws made of 6 to 7 stainless steel wires touch the liquid metal as the top electrode. If the molten metal penetrates the furnace lining and touches the stainless steel sheet (or stainless steel wire mesh), the leak detection alarm device will announce the leak alarm.

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Design of Continuous Casting Machine Foundation

The design of the continuous casting machine foundation is the basic structure design that supports and fixes the continuous casting machine and its related equipment, and transmits various loads and the dynamic loads of the equipment to the foundation through the foundation. The foundation of the continuous caster usually refers to the foundation of the ladle turret, intermediate tank, crystallizer, tension leveling device and shearing machine. Some of the columns of the continuous caster steel platform are also fixed on it. The main contents of the design include the collection of original data, basic form, basic calculation and basic structure.

The basic type of continuous casting machine has a variety of models such as vertical continuous caster, vertical bending, horizontal continuous caster, arc and multi-point bending. Continuous casting methods are divided into single-stream and multi-stream. Casting products include slabs, square billets, round billets and octagonal billets. The operation of casting billets is generally carried out by placing the ladle on a turntable or directly hoisting the ladle on a crane. Therefore, the basic forms are also different.

The structure of the foundation of the continuous caster is more complicated. From the ladle turret to the foundation of the shearing machine, the height is uneven. According to the design of some projects, the top level of the foundation is as high as 10~15m, and the height of the base is 5~-8m. Trenches and cable tunnels are arranged in the foundation (see picture). The load of each part of the foundation is quite different. Therefore, it should be based on the foundation design plan (such as natural foundation or pile foundation, etc.), the layout of process equipment, the distribution of the load of each part, the layout of the channel in the foundation, and the relevant design specifications. The specified allowable maximum length of the foundation and other conditions, reasonably determine the location of the foundation deformation joints. The foundation of the continuous caster is a mixture of block type, wall type, frame type, box type, pit type, beam, plate type and other structural forms.

The loads and external forces acting on the foundation include:

(1) The weight of the equipment acting on the foundation and the structural dead weight from the steel platform of the continuous caster and the weight of the equipment acting on the steel platform, and the single molten steel when the continuous casting machine is running. The deadweight, molten steel weight and operating load of the ladle and double ladle.

(2) Horizontal force, bending moment and torque generated during equipment operation.

(3) The external force generated by abnormal operation during the production process, for example, the vibration caused by the unstable operation when the ladle is placed on the turntable. In this case, the weight of the molten steel and the ladle is generally multiplied by the power coefficient. Since the ladle can change positions on the turntable, the unfavorable load combination generated when the ladle is at different positions must be considered.

The calculation points of the foundation are as follows:

(1) When the various parts of the foundation of the continuous caster are decomposed into wall, frame, box, pit or beam-slab components, the internal force and reinforcement must be carried out according to their actual stress conditions. (2) When the cable tunnel and the water trench are located at the edge of the foundation, where the trench wall is thin, and the groundwater level is higher than the bottom elevation in the trench, the influence of groundwater pressure on the bearing capacity of the trench must be considered and the crack width must be checked.

(3) The center of gravity of the applied load, the weight of the overburden and the weight of the foundation and the centroid of the bottom of the foundation should be located on the same vertical line as far as possible. Check the bearing capacity of the foundation based on the above loads.

(4) When the foundation of the continuous casting machine is built in the seismic fortified area, the seismic check calculation must be carried out. When the foundation is built on a soft soil site, pile foundations or other artificial foundations can be used.

The basic structure of the continuous caster is mainly as follows:

(1) The ladle turret and its supporting frame or wall underneath are generally subjected to high strength, so the concrete with strength grade C25 or C30 is generally adopted the continuous caster foundation adopt C20 or C25. Concrete.

(2) The foundation is made of ordinary reinforced concrete. On the top of the ladle turret, it is necessary to locally build refractory bricks vertically and horizontally to insulate the foundation body according to the requirements of the process. When the refractory bricks are erected vertically, they need to be tied with the embedded steel bars of the foundation.

(3) The anchor bolts of the equipment are mostly deadbolts buried at one time. In the range of the ladle turret platform, T-head live bolts are generally used. For large continuous casting machine, prestressed bolts should be used. Since bolts are mostly made of high-strength steel, electric welding and fire are strictly prohibited during construction and installation.

(4) Reasonably choose the location of construction joints, and it is not advisable to set up more construction joints to facilitate the integrity of the foundation. During construction, it is necessary to take appropriate measures according to the construction season to avoid shrinkage cracks during concrete pouring.

(5) Settlement observation points should be embedded in the four corners of the foundation exposed to the ground.

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Factors Affecting the Quality of High-speed Wire Rod Laying Head

The laying head is the key equipment of high-speed wire rod production. It is arranged after finishing rolling mill, which plays an important role in winding the wire into a certain diameter coil and then spreading it on the air-cooled roller. The quality of the coil produced by the spinner has a great influence on the subsequent winding and packaging processes, especially for the products after packaging.

1. The main factors affecting the quality of wire rod

In the production of a high-speed wire rod mill, the coil quality of the laying head is often unsatisfactory, that is, the coil is oval, the coil is larger or smaller, and the stack is disordered and uneven on the air-cooled line, especially when rolling small-size wire rod. From the spinneret's work process, the spinneret's speed and the laying head is the main influencing factor.

(1) Spinneret

The spinneret is installed on the spinning disk, which is a spiral curve with a spatial cone shape. Although the curves of various manufacturers are different, they can be divided into three sections: first, the initial section is straight, and the wire rod does not undergo plastic bending deformation; The second is the deformation section in which the wire is deformed plastic with the bending shape of the spinneret; Thirdly, the wire rod continues to deform and form a stable coil. The shaping section is very important for the shape of the spinning coil. The end section of the exit of the spinneret is generally at an angle with the spinning pan surface to make the outgoing coil produce forward speed. Then, the overall and horizontal surface of the spinneret is 10 °～ 20 °, and the coil can be ejected smoothly from the spinneret and spread on the air-cooled roller table. 

The angle of the pipe mouth of most spinnerets is not adjustable. Therefore, when the rolling speed changes, the horizontal forward speed of the coil is different, which will cause the coil falling on the air cooling roller table to deviate from the set best condition, that is, the unsatisfactory ring shape will appear. Therefore, the first section of the air cooling roller table is designed to be adjustable in height, so that the vertical distance from the spinning plate to the air cooling roller can be adjusted. By adjusting the height of the roller table, the coil can be correctly laid on the roller table. However, in actual production, it is difficult to master due to the lack of operation experience, which leads to the coil falling down obliquely. When producing a small-scale wire rod, the front of the coil is faster than the rear because of the high horizontal speed. When the adjustment height is not the case, the coil will be inclined and placed on the roller table. Because the wire rod is thin and soft, the coil is easy to form an ellipse.

(2) Speed control of the laying head

The diameter of the coil ejected by the spinneret is not constant and the size is not a moment, which will also affect the appearance quality of the bales. Therefore, it is very important to ensure the coil diameter of the spinneret is constant. When the wire passes through the spinneret, the motion state changes from linear motion to circular motion, and the line speed is VW. at this time, the rotating line speed of the pipe mouth of the spinneret is VL. if the size of VW and VL are equal and the direction is opposite, the synthetic speed of the wire rod in the spinneret mouth relative to the earth is 0. Because of the downward inclination of the spinneret, Therefore, the wire rod will be parabolic in three-dimensional coordinates (the vertical direction is free-falling), so that the curvature radius of the wire when it is ejected is constant, namely the coil diameter.

To ensure that different wire specifications can meet the requirements of VL=VW in the whole process of wire drawing, to stabilize the coil diameter, generally, there are two clamping rollers in front of the spinner. There are two clamping systems: one is to clamp the wire in the whole process, and the micro tension control method is adopted to match the speed of the finishing mill, pinch roller and spinner; The second is tail clamping, small-size wire rod adopts tail speed reduction clamping, in order to prevent the phenomenon of rising speed when the tail out of the fine rolling mill, while the large-scale wire rod adopts tail speed up clamping to promote the wire to smoothly exit the spinner and form a circle. When VL≠VW, the velocity of the coil relative to the earth in the direction of the disk surface is not 0, that is, the coil has an angular velocity relative to the earth, so there will be a certain offset in the falling process. When VL>VW, the relative angular velocity direction is consistent with the spinning direction of the spinneret, and the coil will be left (see the rolling line); When VL<VW, the relative angular velocity direction is opposite to the spinning direction of the spinneret, and the coil will be shifted to the right. When the coil is left or right, it will collide with the side plate of the air-cooled wire and damage the wire surface.

2. Common failures and treatment methods in production

(1) Spinning machine tail-flick

It refers to the phenomenon that the tail of the wire rod can not be ejected smoothly from the spinneret and collides with the spinning surface of high-speed spinning. The reason is that the throwing angle of the pipe mouth is small, and the forward speed of the wire rod is not enough to make the tail leave the spinning surface. The solution is to adjust the throwing angle of the spinneret properly, but for the tail clamping process, it is necessary to ensure the clamping roller is reliable.

(2) Uneven loops of the laying head

It refers to the diameter of the coil that the spinneret spits out is different. The reason is generally related to the speed matching between the spinneret and the finishing mill. It can be solved by adjusting the advanced amount of the spinning. When producing a small wire rod, it is easy to produce a large circle phenomenon at the tail, because the tail will gradually increase speed when leaving the finishing mill, while the speed of the spinneret changes very little, so the diameter of the tail ring becomes larger; For large-scale wire rod, especially the round bar with ribs, most factories adopt tail nonpinch process to ensure the surface quality of wire rod, which will lead to the speed of wire rod end entering the spinner, and thus reduce the coil diameter. Therefore, it is suggested to clamp the tail of a large-size wire rod, and reduce the clamping pressure of the clamping roller to avoid damage to the surface.

（3） Uneven tiling

In order to make the coil evenly spread on the air-cooled roller, the other important factor is the spinning pipe, except that the speed of the roller bed must be constant. When a spinneret produces several specifications of wire, the quality of the coil is often unstable, and it is easy to spread uneven or spit the size circle. This is because wires of different specifications have different spinning speeds, which produce grooves with different trajectories in the spinning tube. Wires passing through this tube are prone to trajectory deviation. Therefore, the best solution is to replace different spinneret tubes when rolling different specifications. When rolling small sizes, one pipe can be used to match one variety, while rolling large size (e.g More than Φ10 mm) a threaded pipe can be shared when the wire rod is used.

（4） The coil is oval

When the small wire is produced and the temperature of spinning is too high, it is easy to appear circle ellipse, because of the soft wire. In addition, the air-cooled roller table height is too low, the coil falling distance of the spinneret is too large, it is also easy to appear ellipse. When the front throw angle of the pipe mouth is too large, the wire rod has a large forward split speed, which causes the coil to fall into the roller table obliquely. For the spinner without head positioning function, the coil is easy to be stuck in the gap of the roller table and the production accident occurs. Therefore, to solve these problems, we must analyze and solve the problems from three aspects: the throwing angle of the spinning pipe, the height of the roller table, and the spinning pipe's temperature.

If you are interested in the laying head or wire rod production line, please mail at marketing2@hanrm.com.

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5 T Induction Furnace for Sale

The 5-ton Induction furnace is generally used in the foundry industry. It uses waste metal to melt molten steel to cast rolls or large castings. Most of them are steel shell furnaces. That is to say, the shell of the medium frequency melting furnace is welded with profiles, and the coil periphery is equipped with a yoke. Generally, it uses a hydraulic tilting furnace and cooling tower for cooling. Its power supply forms include parallel resonance and series resonance.

1. Main Uses of 5t Induction Furnace

The 5T induction melting furnace is mainly used for melting waste steel, iron, copper, aluminum and alloy. The rated capacity of the furnace body is 5000kg. It has the characteristics of high smelting efficiency, good energy-saving effect, uniform metal composition, small combustion, fast heating and easy temperature control.

2. Composition of 5t Medium Frequency Melting Furnace
The 5T medium frequency melting furnace is composed of a medium frequency power supply, capacitor bank, steel shell furnace body, magnetic yoke, leakage alarm device, water cooling cable, induction coil, hydraulic tilting system, tilting console and cooling tower.

3. Price of 5t Foundry Melting Furnace
The price of 5 tons foundry melting furnace is calculated according to the power of medium frequency power supply and the volume of the furnace body. Different configurations have different prices.

4. Configuration

5. Parameter

If you are interested, please mail at marketing2@hanrm.com for your customized solution.

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What Is the Principle Of the Electric Induction Furnace?

Electric induction furnace is an induction heating equipment for bar, round steel, square steel, billet, steel pipe, steel plate, and other metals. The heating temperature is generally no more than 1250 degrees, which is suitable for pre forging heating in the forging industry and metal quenching and tempering heating in the heat treatment industry.

1. Heating principle of medium frequency induction heating furnace

The relationship between the heating coil and the heated material (metal) of the electric induction furnace is the same as that of the coil on the primary and secondary sides of the transformer. The magnetic force line generated by the heating coil through the intermediate frequency current is concentrated on the heated object and induced by the electromagnetic, which generates vortex current, and the heated object will be heated.

According to the type and shape of metal, the proper frequency, power, heating time, holding time, coil shape of AC current can be selected to make the metal heating meet the heating process requirements.

2. Temperature distribution of medium frequency induction heating furnace

The uniformity of radial temperature of non-ferrous metals such as steel bar, aluminum bar, and copper bar in electric induction furnace depends on the correct selection of power frequency and heating time matching the diameter of the workpiece; The axial temperature is uniform and gradient temperature difference depends on the structure and heating mode of the sensor. The inductor structure of the electric induction furnace adopts a spiral heating coil, each group of multi-layer coils can control power independently to realize gradient heating. Generally speaking, an induction furnace is used to make induction penetration of metal materials for extrusion or forging.

3. The equipment of the electric induction furnace is composed of:

The intermediate frequency induction heating furnace consists of a feeding mechanism, mobile trolley, feeding mechanism, induction heating furnace, furnace cover mechanism, discharging roller and ingot carriage, operation control system, main circuit control system, and furnace transformer.

4. Technical parameters of electric induction furnace

⑴Power supply system: double rectifier 12 pulses 1600kw/500hz intelligent induction furnace power supply.

⑵ Heating varieties: carbon steel, alloy steel, high-temperature alloy steel, anti-magnetic steel, stainless steel, titanium material, aluminum alloy, copper alloy, etc

⑶ Main purpose: for the heat transmission forging of rod and round steel.

⑷ Material storage system: thick wall square pipe welded to form a storage platform with a slope of 13 °， 6-8 materials can be stored.

⑸ Feeding system: double clamp roller pneumatic pressure, continuous feeding, step-less speed adjustment of feed speed.

⑹ Discharging system: the quick discharging manipulator is composed of a gas-liquid force increasing cylinder, straight guide rail, open and close chuck, and PLC system.

⑺Sorting system: it is composed of an infrared thermometer, chain transmission, and guide cylinder.

⑻ Energy conversion: heating to 1050 ℃ per ton of steel, and power consumption 310-330 ℃.

⑼ Provide remote operation platform with touch screen or industrial control system according to the user's needs.

⑽ Specially customized human-machine interface, highly humanized operation instructions.

⑾ Full digital, high-depth adjustable parameters, so that you can control the equipment.

5. Features of medium frequency induction furnace:

⑴ The heating speed of the electric induction furnace is fast with little oxide scale. The medium frequency heating furnace uses the principle of electromagnetic induction, and the heat is generated by eddy current in the workpiece itself. It is especially suitable for precision forging.

⑵ The inductors of the electric induction furnaces are interchangeable. There are many kinds of heating equipment in the production process, so it is necessary to set up a variety of induction heaters with a common frame. At this time, the sensor exchange can be completed in a very short time through the unique total up and down water quick-change connector of the electric furnace and the new channel exchange mechanism developed by the electric induction furnace.

⑶ There are many kinds of feeding and discharging structures in the medium frequency induction furnaces. According to customers' different process requirements, the electric induction furnace is equipped with different feeding and discharging machines to form the optimized combination of equipment. The specific forms include continuous type, intermittent type, etc. The discharging forms include tilting type, direct tilting type, etc.

⑷ The whole medium frequency induction heating furnace system of the electric induction furnace can be equipped with an automatic feeding machine, discharging machine, discharging separator, and closed water circulation system according to the user's requirements.

⑸ The whole medium frequency induction heating furnace system of the electric induction furnace has multiple protections, including water temperature and water pressure alarm of cooling water circuit, and upper and lower limit alarm of temperature.

⑹ Stability of the whole medium frequency induction heating furnace system of the electric induction furnace. The continuous feeding of large bars can reduce the impact on the medium-frequency power supply. The closed-loop control of temperature is composed of the power supply to ensure that the head and tail of the return heating temperature are consistent, and the temperature difference between the core and the meter is small.

6. Cost of electric induction furnace

⑴ First of all, many manufacturers sell steel bar medium frequency induction heating furnace equipment on the market. If there are different manufacturers, the price may be different. Sometimes the price of an induction heating furnace is very different, and the price is different.

⑵ If the model of the induction furnace is different, the price is different. There are many models and styles of steel bar electric induction furnaces. Different models of steel bar heating furnaces have different prices.

⑶ Different brands of steel bar medium frequency induction heating furnaces have different prices. Not only in the electric induction furnace industry, but the product brand is also different, the price is different. In any industry, such as cosmetics, mobile phones, computers, and so on, the price of the brand directly affects the price of the product. The same is true for steel bar induction furnaces. The price difference between a big brand and a small brand is very big. However, it is still recommended to buy equipment of powerful brands with a guarantee in terms of quality and after-sales.

⑷ If the electric induction furnace manufacturing process is different, the price is different. At present, there are many manufacturers of steel bar induction heating furnaces in the market. Different induction heating furnace equipment manufacturers have different technical strengths, different production processes, different production costs, and different steel bar heating furnaces. Welding, machining, assembling, and painting of steel bar electric induction furnace are needed. The price of each process is different due to different technology and method.

⑸ The material and configuration of medium frequency induction furnaces are different, and the price is different. The cost of material is an important reason that affects the price of steel bar electric induction furnace. In addition, the configuration of the steel bar induction heating furnace is the same. If a set of steel bar heating furnaces is equipped with many advanced configurations and plays a greater role in the machine, the price will be much higher.

To sum up, the medium frequency induction heating furnace is an electric induction furnace that uses the principle of electromagnetic induction to heat metal, which is widely used in high-temperature heating and low-temperature heating, forging industry, casting industry, and metal quenching and tempering heating in high-temperature heating, and steel pipe anti-corrosion spraying preheating in low-temperature heating. The medium frequency induction heating furnace has become indispensable heating equipment.

If you are interested in the electric induction furnace, please mail at marketing2@hanrm.com for your solution.

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