CN216540765U - Intelligent continuous casting system - Google Patents

Abstract

The utility model relates to the technical field of metal processing, in particular to an intelligent continuous casting system which comprises a hot melting furnace and a continuous casting robot, wherein the continuous casting robot is used for driving a crystallizer arranged on the continuous casting robot to move, so that a metal solution in the hot melting furnace enters the crystallizer, the crystallizer can move in the vertical direction and the horizontal direction by driving the crystallizer to move by using the continuous casting robot arranged in an arm wrist manner, the switching between upward continuous casting and horizontal continuous casting is formed, one continuous casting device can be simultaneously suitable for upward continuous casting work and horizontal continuous casting work, and the technical problem that the function of the conventional continuous casting device is single is solved.

Description

Intelligent continuous casting system

Technical Field

The utility model relates to the technical field of metal processing, in particular to an intelligent continuous casting system.

Background

The quality of the metal continuous casting material has decisive significance for the subsequent processing of metal. In particular for copper or copper alloys, which are common materials for conductors, the purity and the stability of the composition have a great influence on the final product. The application scenes facing the conductor material are various, and the continuous casting technology and equipment are required to have the characteristics of flexibility and reliability. At present, no matter copper alloy is introduced or horizontally continuously cast in industrial application, a furnace body and a continuous casting mechanism are heavy, particularly, the furnace body adopting the melting channel type power frequency induction heating needs to be built, a converter or a furnace washing process, equipment is heavy, the temperature rise is slow, the yield and the flexibility of the equipment are in inverse proportion, the working efficiency is low when products with different components are replaced, and the cost is high.

In addition, the existing casting equipment can only be singly applied to upward continuous casting or horizontal continuous casting, the purpose of switching operation between upward continuous casting and horizontal continuous casting cannot be achieved, in the continuous casting working process, after the molten metal in the furnace body is consumed, the molten metal in the crucible can be continuously consumed through the molten metal in the upward crucible, the purpose of no residual molten metal is achieved, and the phenomenon that the molten metal is remained after each continuous casting operation is finished, scaling in the crucible is caused, and the furnace needs to be repeatedly washed is avoided.

The utility model with the patent application number of CN01122700.1 discloses a production method of a copper alloy up-drawing continuous casting tube blank. The technology relates to the technical field of non-ferrous metal rolling industry. The technical problem of the upward continuous casting pipe is well solved from the aspects of cast pipe production operation method, process control and final control by improving the common upward continuous casting furnace model, matching with a flow guide device, adopting a special crystallizer and a computer automatic control system, and realizing the purpose that the upward continuous casting pipe blank is directly used for pipe positioning and stretching.

Although the above patent discloses a method for producing a copper alloy up-drawing continuous casting tube blank, the technical solution disclosed in the patent does not solve the technical problems mentioned in the background art.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems, the utility model provides an intelligent continuous casting system, which drives a crystallizer to move by using a continuous casting robot arranged in an arm wrist type manner, so that the crystallizer can move in the vertical direction and move in the horizontal direction to be switched, the switching between upward continuous casting and horizontal continuous casting is formed, one piece of continuous casting equipment can be simultaneously suitable for upward continuous casting work and horizontal continuous casting work, and the technical problem of single function of the conventional continuous casting equipment is solved.

In order to achieve the purpose, the utility model provides the following technical scheme:

an intelligent continuous casting system, includes the hot melt stove, still includes:

and the continuous casting robot is used for driving the crystallizer arranged on the continuous casting robot to move so that the metal solution in the hot melting furnace enters the crystallizer.

As an improvement, the continuous casting robot drives the crystallizer used for leading up continuous casting work to move along the vertical direction and stretch into the continuous casting area of the hot melting furnace, and after the crystallizer consumes the molten metal in the continuous casting area after the continuous casting work is performed, the continuous casting robot drives the crystallizer to stretch into the crucible of the hot melting furnace to lead up the molten metal to perform continuous casting work.

As the improvement, continuous casting robot drives and is used for horizontal continuous casting work the crystallizer removes along the horizontal direction and gets into horizontal continuous casting interface on the hot melting furnace makes the metal liquid in the continuous casting district of hot melting furnace enters into through horizontal continuous casting interface carry out horizontal continuous casting work in the crystallizer, work as the crystallizer consumes to finish behind the metal liquid in the continuous casting district, continuous casting robot drives the crystallizer that is used for horizontal continuous casting work after changing and stretches into draw up metal liquid in the crucible of hot melting furnace and carry out continuous casting work.

As an improvement, the continuous casting robot is in the form of an arm wrist, the continuous casting robot and the hot melting furnace are arranged in a split manner, one end of the arm wrist of the continuous casting robot is fixedly arranged, and the other end of the arm wrist of the continuous casting robot is a movably arranged working end and is used for driving the crystallizer to move in the vertical direction or the horizontal direction.

As an improvement, a clamping mechanism for quickly disassembling and assembling and replacing the crystallizer and a traction mechanism for drawing a casting rod produced after the crystallizer is cooled are arranged on the working end of the continuous casting robot.

As an improvement, the hot melting furnace comprises a heating area and a continuous casting area which are arranged side by side, the heating area is communicated with the bottom of the continuous casting area through a communicating hole, and a crucible is arranged at the bottom of the heating area.

As an improvement, the crucible is arranged in a straight cylinder shape and is used for heating the metal contained in the crucible.

As an improvement, an induction heating coil is wound on the outer wall of the crucible and synchronously heats the crucible, the heating zone and the continuous casting zone.

As an improvement, a cooling flow passage for cooling the induction heating coil is arranged in the induction heating coil.

The utility model has the beneficial effects that:

(1) according to the utility model, the continuous casting robot arranged in the cantilever type is used for driving the crystallizer to move, so that the crystallizer can move in the vertical direction and move in the horizontal direction for switching, and the switching between the upward continuous casting and the horizontal continuous casting is formed, so that one continuous casting device can be simultaneously suitable for the upward continuous casting work and the horizontal continuous casting work, and the technical problem of single function of the conventional continuous casting device is solved;

(2) the continuous casting robot and the hot melting furnace are arranged in a split mode, so that the hot melting furnace can be switched rapidly, and when different metals are continuously cast, the continuous casting processing of different metals can be carried out by using the same continuous casting equipment by replacing the hot melting furnace and the crystallizer;

(3) according to the utility model, the hot melting furnace is improved, the traditional crucible is transformed into the communicating vessel for communicating the heating area with the continuous casting area, when the crucible is used for heating molten metal, new metal materials are put into the heating area, so that the metal liquid in the continuous casting area can not be stirred, and the continuous casting processing quality of the crystallizer is improved;

(4) according to the utility model, the induction heating coil is wound on the U-shaped crucible, the electromagnetic induction of the induction heating coil is utilized to heat the crucible, and meanwhile, a heating source is formed at the center of the surrounding area of the crucible, so that the heating area of the hot melting furnace body and the continuous casting area are heated simultaneously, and the temperature of the metal liquid in the heating area and the continuous casting area is kept balanced.

In conclusion, the utility model has the advantages of wide adaptability, multiple functions, excellent casting performance and the like, and is particularly suitable for the technical field of metal processing.

Drawings

FIG. 1 is a side view of the structure of the embodiment of the present invention;

FIG. 2 is a schematic view of a clamping mechanism according to the present invention;

FIG. 3 is a schematic diagram of a side view structure according to an embodiment of the present invention;

FIG. 4 is a schematic view of a triple-furnace according to an embodiment of the present invention;

FIG. 5 is an enlarged schematic view of the communicating holes of the heating zone and the continuous casting zone according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the equipment or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be considered as limiting the present invention. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically defined otherwise.

The first embodiment is as follows:

as shown in fig. 1 and 2, an intelligent continuous casting system includes a furnace 1, and further includes:

and the continuous casting robot 2 is used for driving the crystallizer 3 mounted on the continuous casting robot 2 to move, so that the metal solution in the hot melting furnace 1 enters the crystallizer 3.

Further, place continuous casting machine people 2 drives and is used for drawing continuous casting work crystallizer 3 removes along vertical direction, stretches into in the continuous casting district 12 of hot melt furnace 1, through crystallizer 3 carries out continuous casting work and finishes after the metal liquid in the continuous casting district 12, continuous casting machine people 2 drives crystallizer 3 stretches into draw metal liquid in the crucible 13 of hot melt furnace 1 and carry out continuous casting work.

Wherein, continuous casting machine people 2 is the arm wrist formula, this continuous casting machine people 2 with hot melt stove 1 is the components of a whole that can function independently setting, and the fixed setting of one end of this continuous casting machine people 2 arm wrist, the work end that the other end set up for the activity is used for driving crystallizer 3 removes along vertical direction or horizontal direction.

Furthermore, a clamping mechanism 4 for quickly disassembling and replacing the mold 3 and a traction mechanism 5 for drawing the casting rod produced after the mold 3 is cooled are installed on the working end of the continuous casting robot 2.

It should be noted that the arm-wrist type continuous casting robot 2 drives the crystallizer 3 to move in the vertical direction, so that the crystallizer 3 can descend into the continuous casting area 12 of the hot melting furnace 1, so that the metal liquid enters the crystallizer 3, a cooling cavity is arranged on the crystallizer 3, a cooling liquid flows through the cooling cavity, the cooling liquid cools the metal liquid in the crystallizer 3 to form a casting rod, the casting rod is upwards pulled by the pulling mechanism 5, and the casting rod is wound by the winding system 6.

It is further explained that the hot melting furnace 1 and the continuous casting robot 2 are separately arranged, so that when different metals are continuously cast, the hot melting furnace 1 and the crystallizer 3 can be replaced to quickly perform continuous casting of other metals.

More specifically, the clamping mechanism 4 includes a base 41, a lower clamping assembly 42 and an upper clamping assembly 43, the lower clamping assembly 42 includes a lower clamping plate 421 and a fixture block 422 rotatably disposed, the lower clamping plate 421 is provided with a clamping groove 4211 for mounting a lower end portion of the mold 3, the fixture block 422 is rotatably mounted at the clamping groove 4211, the lower end portion of the mold 3 is locked on the lower clamping plate 421 by the fixture block 422 through a threaded fastener 423, the upper clamping assembly 43 includes a clamping block 431 and a clamping hand wheel 432 rotatably disposed, the upper end portion of the mold 3 is clamped and fixed by rotating the clamping hand wheel 432, a positioning plate 44 for assisting in positioning is disposed between the lower clamping assembly 42 and the upper clamping assembly 43, and the positioning plate 44 is provided with a positioning groove 441 for assisting in positioning and mounting the mold 3.

Furthermore, a pulling mechanism 5 is integrated in the continuous casting robot 2, and the pulling mechanism 5 is a pulling mechanism used in a conventional continuous casting apparatus and has a principle of clamping a casting bar by rotating rolls disposed up and down and then pulling the casting bar in cooperation with a collecting device.

An electric control mechanism 7 for controlling the continuous casting robot 2 and the hot melting furnace 1 and a cooling mechanism 8 for cooling the crystallizer 3 are arranged beside the continuous casting robot 2, and the winding device 6, the electric control mechanism 7 and the cooling mechanism 8 are all the prior art structures in the existing continuous casting equipment, so that redundant description is not repeated.

Example two:

FIG. 3 is a schematic structural diagram of a second embodiment of an intelligent continuous casting system according to the present invention; as shown in fig. 3, in which the same or corresponding components as in the first embodiment are denoted by the same reference numerals as in the first embodiment, only the points of difference from the first embodiment will be described below for the sake of convenience. The second embodiment is different from the first embodiment in that:

as shown in fig. 3, the continuous casting robot 2 drives the crystallizer 3 for horizontal continuous casting work to move in the horizontal direction to enter the horizontal continuous casting interface on the hot melting furnace 1, so that the molten metal in the continuous casting area 12 of the hot melting furnace 1 enters the crystallizer 3 through the horizontal continuous casting interface to perform horizontal continuous casting work, and when the crystallizer 3 finishes the consumption of the molten metal in the continuous casting area 12, the continuous casting robot 2 drives the changed crystallizer 3 for horizontal continuous casting work to extend into the crucible 13 of the hot melting furnace 1 to pull up the molten metal to perform continuous casting work.

It should be noted that, a difference from the embodiment is that the crystallizer 3 used in the embodiment is a crystallizer used in horizontal continuous casting, the continuous casting robot 2 drives the crystallizer 3 to horizontally move to a continuous casting interface on the hot-melting furnace 1 for connection, the molten metal in the continuous casting area 12 of the hot-melting furnace body 1 enters the crystallizer 3 through the continuous casting interface, a casting bar is formed after cooling, and the casting bar is drawn by the drawing mechanism 5 and output to be rolled by the rolling device 6.

It should be emphasized here that the continuous casting interface can be automatically closed when the furnace 1 is used for up-drawing continuous casting, avoiding leakage of the molten metal.

And when the metal liquid in the continuous casting area 12 is consumed, the crystallizer 3 for horizontal continuous casting is replaced by a crystallizer for upward continuous casting, the residual metal liquid in the crucible 13 for upward continuous casting is consumed, and the residual metal liquid in the crucible 13 is avoided.

Example three:

FIG. 4 is a schematic structural diagram of a third embodiment of an intelligent continuous casting system according to the present invention; as shown in fig. 4, the same or corresponding components as those in the first and second embodiments are denoted by the same reference numerals as those in the first and second embodiments, and only the differences from the first and second embodiments will be described below for the sake of convenience. The third embodiment is different from the first and second embodiments in that:

as shown in fig. 4 and 5, the hot melting furnace 1 includes a heating zone 11 and a continuous casting zone 12 arranged side by side, the heating zone 11 is communicated with the bottom of the continuous casting zone 12 through a communication hole 10, and a crucible 13 is arranged at the bottom of the heating zone 11.

Further, the crucible 13 is arranged in a straight cylinder shape, and the crucible 13 is used for heating the metal contained in the crucible.

Further, an induction heating coil 14 is wound around the outer wall of the crucible 13, and the induction heating coil 14 heats the crucible 13, the heating zone 11, and the continuous casting zone 12 simultaneously.

It should be noted that, in the conventional hot melting furnace, after the metal block is heated by the crucible to form the metal liquid, the metal liquid enters the continuous casting zone through the communicating holes formed in the heating zone and the bottom of the continuous casting zone to participate in the continuous casting work, but after the metal liquid continuous casting in the continuous casting zone is completed, the residual metal liquid in the crucible is still not continuously cast, and the hot melting furnace 1 of the present application, through the arrangement of the straight-cylindrical crucible 13, can utilize the continuous casting robot to smoothly extend the crystallizer 3 into the crucible 13 to perform the continuous casting work after the metal liquid in the continuous casting zone 12 is completely consumed, so as to consume the metal liquid in the crucible, avoid the metal liquid remaining in the crucible 13 after each work, and effectively avoid the high-frequency furnace washing work.

In addition, an induction heating coil 14 is provided outside the crucible 13, the crucible 13 is heated by medium-frequency or high-frequency electromagnetic induction heating, the metal liquid in the heating zone 11 and the continuous casting zone 12 is heated and kept warm by the heating source, and the three parts of the crucible, the heating zone and the continuous casting zone are efficiently heated and kept warm by the induction heating coil 14 in cooperation with the crucible 13.

It should be emphasized that the shape of the crucible in the present application is not limited to a straight cylinder, and any shape and structure that can connect the heating zone and the continuous casting zone and can continuously and thoroughly conduct the molten metal in the crucible is within the protection scope of the present application.

The working process is as follows:

step A, heating metal, namely heating the metal in a crucible 13 through an induction heating coil 14;

step B, feeding, namely adding metal raw materials into the crucible 13 after the metal in the crucible 13 is melted, and enabling the molten metal liquid to enter a heating area 11 and a continuous casting area 12 of the hot melting furnace 1;

c, stirring, namely slowly stirring the metal liquid in the heating area 11 when the metal liquid in the hot melting furnace 1 reaches the height meeting the casting processing height;

d, upward continuous casting, wherein a cantilever of the continuous casting robot 2 clamps an upward crystallizer and extends into a continuous casting area 12, so that the crystallizer 3 is positioned below the metal liquid level, the metal liquid enters the crystallizer through a multi-filtration device arranged on the crystallizer 3 and forms a casting rod through cooling, a traction mechanism 5 pulls the casting rod to perform continuous upward casting, and a winding system 6 automatically winds the casting rod according to the upward casting speed;

and E, drawing residual liquid upwards, and when the continuous casting of the metal liquid in the hot melting furnace 1 is finished, driving the crystallizer 3 to extend into the crucible 13 by the cantilever of the continuous casting robot 2 to cast the residual metal liquid.

In step a, charcoal is put into the heating zone 11 of the furnace 1, scale graphite is put into the continuous casting zone 12 for anti-oxidation coating, the copper alloy raw material in the crucible 13 is heated by the medium frequency induction heating coil 14, and the temperature of the furnace is automatically controlled by the signal of the temperature sensor.

Further, in step D, the metal liquid feed port portion of the mold 3 is provided with a multi-filtration device. The filtering device is of a multilayer bottle-shaped nested structure, and molten metal flowing channel holes are formed among layers, so that impurities can be effectively prevented from entering the casting rod.

In addition, when the metal liquid level changes after a period of continuous casting work, the liquid level position sensor detects a liquid level height signal, and the robot wrist arm automatically adjusts the position of the crystallizer according to the liquid level height.

Compared with the existing continuous casting method, the method has the great difference that the residual liquid is added, and the crucible arranged in a cylindrical shape is utilized, so that the residual metal liquid in the crucible is consumed through the up-drawing continuous casting work, the metal liquid residue is avoided, the furnace washing times of the hot melting furnace are greatly reduced, and the work efficiency is improved.

In addition, the working process can also be as follows:

step A, positioning an interface, wherein a cantilever of a continuous casting robot 2 clamps a crystallizer 3 and extends into a horizontal continuous casting interface of a continuous casting area 12 on a hot melting furnace 1;

b, heating the metal, namely putting an anti-oxidation covering agent into the furnace body of the hot melting furnace 1, and heating the metal in the crucible 13 through an induction heating coil 14;

step C, feeding, namely adding metal raw materials into the crucible 13 after the metal in the crucible 13 is melted, and enabling the molten metal liquid to enter the heating area 11 and the continuous casting area 12 of the hot melting furnace 1;

d, stirring, namely slowly stirring the metal liquid in the heating area 11 when the metal liquid in the hot melting furnace 1 reaches the height meeting the casting processing height;

e, horizontal continuous casting, wherein when the crystallizer 3 is positioned below the metal liquid level in the continuous casting area 12, the metal melt enters through a multi-filtering device on the crystallizer 3 and is cooled to form a casting rod, the casting rod is dragged by the traction mechanism 5 to be continuously and horizontally cast, and the casting rod is automatically rolled by the rolling system 6 according to the traction speed of the casting rod;

and F, residual liquid is upwards drawn, when the horizontal continuous casting of the metal liquid in the furnace body of the hot melting furnace 1 is finished, the crystallizer 3 for horizontal continuous casting installed on the clamping mechanism 4 is replaced by the crystallizer 3 for upwards drawing continuous casting, and the residual metal liquid is upwards drawn into the crucible 13 along the vertical direction.

It should be noted that, in step a, the continuous casting interface is generally located at the lower part of the continuous casting area 12, so that the molten metal in the continuous casting area 12 is conveniently poured into the crystallizer 3, and a valve is arranged at the continuous casting interface and used for controlling the on-off of the continuous casting interface.

In addition, in step B, charcoal is put into the heating zone 11 of the furnace 1, scale graphite is put into the continuous casting zone 12 for anti-oxidation coating, the copper alloy raw material in the crucible 13 is heated by the medium frequency induction heating coil 14, and the temperature of the furnace is automatically controlled by the signal of the temperature sensor.

Further, in step E, the metal liquid feed port portion of the crystallizer 3 is provided with a multi-filtration device. The filtering device is of a multilayer bottle-shaped nested structure, and molten metal flowing channel holes are formed among layers, so that impurities can be effectively prevented from entering the casting rod.

And the method is greatly different from the prior continuous casting method in that in the step F, horizontal continuous casting is changed into upward continuous casting by replacing the crystallizer, the crystallizer is extended into the crucible, and the residual metal liquid in the crucible is consumed by the upward continuous casting, so that the metal liquid residue is avoided, the furnace washing times of the hot melting furnace are greatly reduced, and the working efficiency is improved.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the utility model, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (8)

1. The utility model provides an intelligence continuous casting system, includes hot melt furnace (1), its characterized in that still includes:

the continuous casting robot (2) is used for driving the crystallizer (3) arranged on the continuous casting robot (2) to move, so that the metal liquid in the hot melting furnace (1) enters the crystallizer (3);

continuous casting machine people (2) drive be used for leading continuous casting work crystallizer (3) remove along vertical direction, stretch into in continuous casting district (12) of hot melt stove (1), through crystallizer (3) carry out the continuous casting work and consume and finish behind the metal liquid in continuous casting district (12), continuous casting machine people (2) drive crystallizer (3) stretch into it draws metal liquid to carry out continuous casting work in crucible (13) of hot melt stove (1).

2. The intelligent continuous casting system of claim 1, wherein:

continuous casting machine people (2) drive and are used for the work of horizontal continuous casting crystallizer (3) move along the horizontal direction and get into horizontal continuous casting interface on hot melt stove (1) makes the metal liquid in continuous casting district (12) of hot melt stove (1) enters into through horizontal continuous casting interface carry out horizontal continuous casting work in crystallizer (3), work as crystallizer (3) consume and finish behind the metal liquid in continuous casting district (12), continuous casting machine people (2) drive be used for horizontal continuous casting work after changing crystallizer (3) stretch into draw metal liquid to carry out continuous casting work in crucible (13) of hot melt stove (1).

3. The intelligent continuous casting system according to any one of claims 1 to 2, wherein:

the continuous casting machine ware people (2) are the arm wrist formula, this continuous casting machine ware people (2) with hot melt stove (1) is the components of a whole that can function independently setting, and the fixed setting of one end of this continuous casting machine ware people (2) arm wrist, the work end that the other end set up for the activity is used for driving crystallizer (3) are followed vertical direction or horizontal direction and are removed.

4. The intelligent continuous casting system according to any one of claims 1 to 2, wherein:

and a clamping mechanism (4) used for quickly dismounting and replacing the crystallizer (3) and a traction mechanism (5) used for drawing the casting rod produced after the crystallizer (3) is cooled are arranged at the working end of the continuous casting robot (2).

5. The intelligent continuous casting system according to any one of claims 1 to 2, wherein:

the hot melting furnace (1) comprises a heating area (11) and a continuous casting area (12) which are arranged side by side, the heating area (11) is communicated with the bottom of the continuous casting area (12) through a communicating hole (10), and a crucible (13) is arranged at the bottom of the heating area (11).

6. The intelligent continuous casting system of claim 5, wherein:

the crucible (13) is arranged in a straight cylinder shape, and the crucible (13) is used for heating metal contained in the crucible.

7. The intelligent continuous casting system of claim 5, wherein:

and an induction heating coil (14) is wound on the outer wall of the crucible (13), and the induction heating coil (14) synchronously heats the crucible (13), the heating zone (11) and the continuous casting zone (12).

8. The intelligent continuous casting system of claim 7, wherein:

and a cooling flow channel for cooling the induction heating coil (14) is arranged in the induction heating coil.

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