WO2020232809A1 - Système de production de ruban nanocristallin à productivité élevée - Google Patents

Système de production de ruban nanocristallin à productivité élevée Download PDF

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Publication number
WO2020232809A1
WO2020232809A1 PCT/CN2019/095320 CN2019095320W WO2020232809A1 WO 2020232809 A1 WO2020232809 A1 WO 2020232809A1 CN 2019095320 W CN2019095320 W CN 2019095320W WO 2020232809 A1 WO2020232809 A1 WO 2020232809A1
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WIPO (PCT)
Prior art keywords
nozzle
horizontal
vacuum furnace
nozzle package
control system
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PCT/CN2019/095320
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English (en)
Chinese (zh)
Inventor
邹黎
邹旭
刘志田
邹雪
袁礼剑
Original Assignee
山东电亮亮信息科技有限公司
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Publication of WO2020232809A1 publication Critical patent/WO2020232809A1/fr

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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22DCASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
    • B22D11/00Continuous casting of metals, i.e. casting in indefinite lengths
    • B22D11/06Continuous casting of metals, i.e. casting in indefinite lengths into moulds with travelling walls, e.g. with rolls, plates, belts, caterpillars
    • B22D11/0637Accessories therefor
    • B22D11/064Accessories therefor for supplying molten metal
    • B22D11/0642Nozzles
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22DCASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
    • B22D11/00Continuous casting of metals, i.e. casting in indefinite lengths
    • B22D11/10Supplying or treating molten metal
    • B22D11/103Distributing the molten metal, e.g. using runners, floats, distributors
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B22CASTING; POWDER METALLURGY
    • B22DCASTING OF METALS; CASTING OF OTHER SUBSTANCES BY THE SAME PROCESSES OR DEVICES
    • B22D11/00Continuous casting of metals, i.e. casting in indefinite lengths
    • B22D11/14Plants for continuous casting

Definitions

  • the invention relates to a nanocrystalline strip production equipment structure, in particular to a large-capacity nanocrystalline thin strip production system.
  • Iron-based nanocrystalline ribbons are known as the most cost-effective soft magnetic materials for their excellent soft magnetic properties, especially nanocrystalline thin ribbons with a thickness of less than 20um, which have low eddy current loss and are highly regarded for their excellent high-frequency characteristics.
  • iron-based nanocrystalline broadband with a width of 60mm or more, it is the first choice for magnetic shielding and wireless charging cores for mobile phones.
  • the current method of obtaining nanocrystalline thin strips in batches in the domestic industry is pressure spraying. Through constant pressure control, the pressure at the nozzle is kept constant, thereby obtaining nanocrystalline ribbons with high density and relatively uniform thickness.
  • the more consistent method of the nanocrystalline strip production line is: after the master alloy is melted to remove the slag, the molten iron is poured into the nozzle pack at one time through the pouring steel diversion groove; then the nozzle pack is sealed and filled with inert gas. There is a narrow slot nozzle at the bottom of the bag, and the high-temperature molten iron in the nozzle bag is sprayed onto the high-speed rotating cooling crystallizer through the nozzle slot, and the ribbon is spun under the action of centrifugal force. Therefore, the nanocrystalline ribbon spraying machine is also called the ribbon spinner.
  • the pressure at the nozzle can be adjusted indirectly by adjusting the air pressure inside the nozzle pack to make the strip density uniform. This spraying method is called nanocrystalline pressure spraying.
  • the current maximum tonnage of the iron-based nanocrystalline pressure spray belt at one time does not exceed 200kg.
  • the mass production of iron-based nanocrystalline ultra-wide and ultra-thin ribbons it is difficult to achieve mass production due to the limitation of the nozzle package volume. At present, this has become a bottleneck restricting the continuous mass production of iron-based nanocrystalline ribbons.
  • the technical problem to be solved by the present invention is to provide a large-capacity nanocrystalline thin strip production system with simple structure, reasonable design, high production efficiency, and can effectively improve the single-spraying yield of the nanocrystalline strip.
  • a large-capacity nanocrystalline ribbon production system includes a rack platform on which a walking track is installed, and a melting station and a pouring track are provided on the walking track.
  • a steel station, a vacuum furnace system reciprocating between the smelting station and the steel pouring station is slidably installed on the walking rail, and the lower part of the frame platform is provided with a corresponding steel pouring station
  • a crystallizer is correspondingly installed under the nozzle pack mechanism, and an automatic take-up device is correspondingly installed on the tape-out side of the crystallizer, and an online thickness measuring device is arranged between the crystallizer and the automatic take-up device, so The online thickness measuring device and the nozzle pack mechanism are electrically
  • the vacuum furnace system includes a platform frame body, a sliding roller is mounted on the bottom end of the platform frame body, the sliding roller is slidably mounted on the walking track, and the platform frame body is mounted
  • a vacuum furnace body and a vacuum system connected with the vacuum furnace body are correspondingly equipped with a vacuum furnace power supply system.
  • a large-capacity smelting furnace is installed in the vacuum furnace body, a side bottom pouring steel device is installed on the side of the large-capacity smelting furnace, and the side bottom pouring steel device corresponds to the side
  • the water outlet of the bottom casting steel pouring device is equipped with a horizontal plug rod assembly; the nozzle pack constant liquid level closed-loop control system is electrically connected between the nozzle pack mechanism and the horizontal plug rod assembly and controls the horizontal plug rod assembly. Horizontal movement of the plug rod assembly.
  • the horizontal stopper assembly and the frame platform are electrically connected with a vacuum furnace pouring opening and closing that controls the opening and closing of the horizontal stopper assembly and switches between the pouring state and the melting state. Control System.
  • the large-capacity smelting furnace includes a furnace body and an induction coil, and the induction coil is provided with a ramming shaped furnace lining;
  • the vertical outlet end of the side-bottom steel casting device is connected with a vertical runner Insulation assembly;
  • the side bottom pouring steel device includes a horizontal inner liquid outlet part communicating with the inner cavity of the furnace lining, the horizontal inner liquid outlet part is sealed with a right-angle outer liquid outlet part;
  • the horizontal plug rod assembly wears Pass through the horizontal section of the right-angle outer liquid outlet part and connect with the horizontal inner liquid outlet part, and the vertical outlet end of the right-angle outer liquid outlet part is connected with the vertical runner insulation assembly;
  • the free end of the section is sealed and sleeved on the outlet end of the horizontal inner outlet part.
  • the right-angle outer outlet part is provided with a horizontal flow channel communicating with the inner cavity of the horizontal inner outlet part and the vertical runner The vertical flow channel connected by the thermal insulation components.
  • the inner cavity of the horizontal inner liquid outlet member is provided with a restrictor table that divides its flow path into an inner liquid inlet channel and an inner liquid outlet channel, and a restrictor is arranged on the restrictor table.
  • the horizontal flow channel communicates with the inner outlet flow channel and the inner diameters of the two flow channels gradually increase along the flow direction of the molten steel
  • the horizontal plug rod assembly includes an end that passes through the right-angle outer outlet part And a side plug rod that abuts on the flow restriction table and blocks the flow restriction hole, the side plug rod is located at the free end outside the right-angle liquid outlet part and is electrically connected to the constant liquid level of the nozzle pack A closed loop control system and the pouring opening and closing control system of the vacuum furnace.
  • the vertical runner insulation assembly includes a fixed shell fixedly connected to the furnace body, and a runner connected to the vertical outlet end of the side bottom pouring steel device is sleeved in the fixed shell
  • the inner lining is provided with a vertical runner corresponding to the water inlet of the nozzle pack mechanism, and an axially extending silicon carbide rod is sleeved between the inner lining of the runner and the fixed shell, An insulation layer is installed between the silicon carbide rod and the fixed shell.
  • the nozzle package mechanism includes a nozzle package body and a nozzle package position adjustment mechanism that controls the distance between the bottom nozzle of the nozzle package body and the upper cut surface of the crystallizer, and the strip thickness constant closed-loop control system It is electrically connected between the online thickness measuring device and the nozzle pack position adjustment mechanism and controls the nozzle pack position adjustment mechanism to adjust the distance between the bottom nozzle of the nozzle pack body and the upper cut surface of the mold.
  • the nozzle pack body is a high-level nozzle pack, a nozzle pack float is arranged in the nozzle pack body, and the nozzle pack float floats on the molten iron surface in the nozzle pack body.
  • the nozzle pack constant liquid level closed-loop control system is electrically connected between the nozzle pack float and the horizontal plug rod assembly and controls the opening range of the horizontal plug rod assembly according to the height of the liquid level in the nozzle pack;
  • a nozzle plug rod is detachably installed in the nozzle package body corresponding to the water outlet of the nozzle package body, a nozzle is installed on the bottom end of the nozzle package body corresponding to the water outlet of the nozzle package body, and the nozzle and the crystallizer Corresponding;
  • the nozzle package body and the water inlet of the nozzle package body are provided with an inert gas protection device to prevent the oxidation of molten steel during the freewheeling process of molten iron.
  • the nozzle wrapper rod and the frame platform are electrically connected with a nozzle wrapper rod opening and closing control that controls the nozzle wrapper rod to switch between a spray band state and a non-spray band state system.
  • the vacuum furnace system adopts a large-capacity smelting furnace and can be moved back and forth as a whole, it is sufficient to directly move the vacuum furnace system to the top of the nozzle pack mechanism.
  • the molten iron is continuously supplied during belt spraying, which increases the cost
  • the amount of secondary spray belt improves production efficiency;
  • the nozzle pack constant liquid level closed-loop control system is used to control the opening and closing amplitude of the water outlet of the vacuum furnace system.
  • the nozzle pack constant liquid level The closed-loop control system will control the water outlet of the vacuum furnace system to increase the opening range, so that the molten steel in the vacuum furnace system will flow into the nozzle pack mechanism; when the molten steel in the nozzle pack mechanism is greater than the set value
  • the nozzle pack constant liquid level closed-loop control system controls the water outlet of the vacuum furnace system to reduce the opening range, so that the molten steel in the vacuum furnace system slows down or stops flowing into the nozzle pack mechanism, which can effectively reduce
  • the molten steel in the nozzle package mechanism is maintained within a set range, so that the molten steel level in the nozzle package structure is maintained at a constant value, and the consistency of the strip density is maintained.
  • the closed-loop control system with constant strip thickness is used to control the distance between the nozzle pack mechanism and the crystallizer.
  • the signal is transmitted to the closed-loop control system with constant strip thickness, and the closed-loop control system with constant strip thickness controls the nozzle pack mechanism to adjust the distance between the nozzle pack mechanism and the mold in real time.
  • the present invention has simple structure, reasonable design, high production efficiency, and can effectively increase the output of nanocrystalline strip in a single spray.
  • Figure 1 is a schematic structural view of a vacuum furnace system in a pouring state according to an embodiment of the present invention
  • Figure 2 is a schematic structural view of the vacuum furnace system in a smelting state according to an embodiment of the present invention
  • Figure 3 is a structural cross-sectional view of a large-capacity smelting furnace according to an embodiment of the present invention
  • FIG. 4 is a structural diagram of an induction coil of an electric furnace according to an embodiment of the present invention.
  • the large-capacity nanocrystalline ribbon production system includes a rack platform 1.
  • the rack platform 1 serves as the mounting base of this embodiment and has a supporting role.
  • a walking rail 2 is installed, the walking rail 2 is provided with a melting station and a steel pouring station, and the walking rail 2 is slidably installed with a reciprocating motion between the melting station and the steel casting station.
  • Vacuum furnace system In this embodiment, the melting station is located at the rear and the steel pouring station is located at the front. When melting is required, the vacuum furnace system moves backward as a whole.
  • the vacuum furnace system moves forward as a whole to meet the different requirements of the melting station and the steel casting station; the lower part of the frame platform 1 corresponds to the steel casting station with a nozzle package corresponding to the vacuum furnace system Mechanism, the nozzle package mechanism and the vacuum furnace system are electrically connected with a nozzle package constant liquid level closed-loop control system that controls the opening and closing amplitude of the water outlet of the vacuum furnace system; the nozzle package mechanism is correspondingly installed below In the crystallizer 3, an automatic take-up device 4 is correspondingly installed on the tape-out side of the crystallizer 3.
  • the automatic take-up device 4 realizes automatic take-up of the belt by means of negative pressure adsorption; the crystallizer 3 and the automatic take-up An online thickness measuring device 5 is arranged between the devices 4, the crystallizer 3, the automatic take-up device 4, and the online thickness measuring device 5 belong to the prior art, and the specific structure is not repeated here;
  • the thickness measuring device 5 and the nozzle pack mechanism are electrically connected with a closed-loop control system of constant strip thickness for controlling the distance between the nozzle pack mechanism and the crystallizer 3.
  • the smelting station is located at the rear and the steel casting station is located at the front.
  • the vacuum furnace system moves backward as a whole.
  • the vacuum furnace The system moves forward as a whole to meet the different requirements of the smelting station and the steel pouring station; since the vacuum furnace system can be moved back and forth as a whole, the vacuum furnace system can be moved directly above the nozzle pack mechanism.
  • the large-capacity smelting furnace can continuously supply molten iron during the band spraying process, effectively reducing the distance of the molten iron runner, reducing the oxidation and heat loss of the molten steel during the pouring process, and saving electric energy.
  • the nozzle package constant liquid level closed-loop control system is used to control the opening range of the water outlet of the vacuum furnace system.
  • the nozzle package constant liquid level closed-loop control system The water outlet of the vacuum furnace system will be controlled to increase the opening range so that the molten steel in the vacuum furnace system will flow into the nozzle pack mechanism; when the molten steel in the nozzle pack mechanism is greater than the set value, The nozzle pack constant liquid level closed-loop control system controls the water outlet of the vacuum furnace system to reduce the opening range, so that the molten steel in the vacuum furnace system reduces or stops flowing into the nozzle pack mechanism, which can effectively
  • the molten steel in the nozzle pack mechanism is maintained within a set range, so that the molten steel level in the nozzle pack mechanism is maintained at a constant value and the consistency of the strip is maintained.
  • the strip thickness constant closed-loop control system is used to control the distance between the nozzle pack mechanism and the crystallizer 3.
  • the signal is transmitted to the closed-loop control system with constant strip thickness, and the closed-loop control system with constant strip thickness controls the nozzle package mechanism to adjust the distance between the nozzle package mechanism and the mold 3 in real time.
  • the vacuum furnace system includes a platform frame body 6, a sliding roller 7 is installed at the bottom end of the platform frame body 6, and the sliding roller 7 is slidably mounted on the walking rail 2 to realize the reciprocation of the vacuum furnace system Movement, the platform frame 6 is equipped with a vacuum furnace body 8 and a vacuum system 9 connected to the vacuum furnace body 8.
  • the vacuum system 9 is correspondingly equipped with a vacuum furnace power supply system 10, the vacuum system 9 and The vacuum furnace power supply system 10 belongs to the prior art, and will not be repeated here.
  • a large-capacity smelting furnace is installed in the vacuum furnace body 8.
  • the single-shot molten iron supply of the nanocrystalline strip production line is increased, that is, the single-spraying output of the nanocrystalline strip production line is increased, and the production efficiency is improved.
  • the side of the large-capacity smelting furnace is correspondingly installed with a side bottom pouring steel device 11, and the side bottom pouring steel device 11 is equipped with a horizontal plug rod assembly corresponding to the water outlet of the side bottom pouring steel device 11
  • the side and bottom pouring device 11 is provided for side and bottom pouring steel, compared with the prior art tilting pouring method, because this embodiment does not use a tilting furnace when pouring steel Therefore, the furnace body occupies a small space and saves space.
  • the side bottom pouring method reduces the length of the molten iron flow channel and reduces the molten steel oxidation burning loss;
  • the nozzle package constant liquid level closed-loop control system is electrically connected to the nozzle package mechanism Between and controlling the horizontal movement of the horizontal plug rod assembly.
  • the large-capacity smelting furnace includes a furnace body 15 in which an induction coil 17 is installed, and the induction coil 17 is provided with a ramming shaped furnace lining 16; the side bottom casting and pouring device The vertical outlet end of 11 is connected with a vertical sprue insulation assembly; the side bottom pouring steel device 11 includes a horizontal inner liquid outlet part 18 communicating with the inner cavity of the furnace lining 16, and the horizontal inner liquid outlet part 18 is sealed on A right-angled liquid-outlet part 23 is installed; the horizontal plug rod assembly passes through the horizontal section of the right-angled liquid-outlet part 23 and is connected to the horizontal inner liquid-outlet part 18, and the vertical outlet of the right-angled liquid-outlet part 23 End is connected with the vertical runner insulation assembly; the free end of the horizontal section of the right-angle outer liquid outlet part 23 is sealed and sleeved on the liquid outlet end of the horizontal inner liquid outlet part 18, and the right-angle outer liquid outlet part 23 is provided with The horizontal flow channel 24 communicated with the inner cavity of the horizontal
  • the inner cavity of the horizontal inner liquid outlet member 18 is provided with a restrictor 21 that divides its flow path into an inner liquid inlet channel 19 and an inner liquid outlet 20, and a restrictor hole is provided on the restrictor 21 22;
  • the horizontal flow passage 24 is in communication with the inner outlet flow passage 20 and the inner diameters of the two flow passages gradually become larger along the flow direction of the molten steel;
  • the horizontal plug rod assembly includes an end that passes through the right angle out The liquid part 23 abuts against the restrictor 21 and blocks the side plug rod 26 of the restrictor hole 22, and the side plug rod 26 is located at the free end of the right-angle outer liquid outlet part 23 and is electrically connected To the closed-loop control system of the nozzle pack constant liquid level.
  • the vertical runner insulation assembly includes a fixed shell 27 fixedly connected to the furnace body 15, as shown in FIG. 4, the fixed shell 27 is sheathed with the vertical outlet end of the side bottom pouring steel device
  • the runner liner 28 is provided with a vertical runner corresponding to the water inlet of the nozzle pack mechanism, and a shaft is sleeved between the runner liner 28 and the fixed housing 27
  • a silicon carbide rod 30 extending in the direction, the silicon carbide rod 30 is configured as a double-threaded silicon carbide rod, and an insulating layer 29 is installed between the silicon carbide rod 30 and the fixed housing 27.
  • the large-capacity smelting furnace controls the pouring of steel through the opening and closing of the side stopper 26.
  • steel When steel is required to be poured, it is only necessary to travel the melting furnace to the upper part of the nozzle pack mechanism through the track, and aim at the water inlet of the nozzle pack mechanism for pouring.
  • Steel just open the side plug 26 and pour steel.
  • This kind of electric furnace structure organically integrates smelting, heat preservation and steel pouring control, avoids heat loss in the process of molten steel transfer, and simplifies operation.
  • the flow of molten steel is controllable, and the side plug 26 can be switched on and off timely according to requirements, and the flow of molten steel can be adjusted according to requirements to avoid waste of molten steel overflowing.
  • the nozzle pack mechanism includes a nozzle pack body 12 and a nozzle pack position adjustment mechanism 13 that controls the distance between the bottom nozzle of the nozzle pack body 12 and the upper cut surface of the crystallizer 3.
  • the nozzle pack position adjustment mechanism 13 has front and back , Up and down, left and right, and front and rear tilt angle adjustment three-dimensional adjustment structure, the specific mechanism belongs to the prior art, and will not be repeated here; the strip thickness constant closed loop control system is electrically connected to the online thickness measurement device 5 and the nozzle package The position adjustment mechanism 13 and the nozzle pack position adjustment mechanism 13 are controlled to adjust the distance between the bottom nozzle of the nozzle pack body 12 and the upper cut surface of the crystallizer 3.
  • the online thickness measuring device 5 is used for online monitoring of strip thickness and deviation, and transmits the signal to the closed-loop control system for the constant thickness of the strip.
  • the closed-loop control system for constant strip thickness will control the nozzle pack position adjustment mechanism 13, and the nozzle pack position adjustment mechanism 13 will The nozzle package body 12 is driven to move forward and backward, up and down, left and right, and forward and backward inclination to adjust the distance between the water outlet of the nozzle package 12 and the water inlet of the crystallizer 3 until the online thickness measurement device 5 monitors
  • the closed-loop control system for the constant strip thickness will control the nozzle pack position adjustment mechanism 13 to stop.
  • the nozzle package 12 is a high-level nozzle package, and a high-level spray belt method is adopted to increase the pressure of the spray belt and increase the density of the strip.
  • the nozzle package 12 and An inert gas protection device for preventing the oxidation of molten steel during the freewheeling process of the molten iron is also provided at the water inlet of the nozzle package body 12 to prevent oxidation of the surface of the molten iron.
  • the inert gas protection device belongs to the prior art and will not be repeated here.
  • the nozzle package body 12 is provided with a nozzle package float, the nozzle package float floats on the molten steel surface in the nozzle package body 12, the nozzle package constant liquid level closed-loop control
  • the system is electrically connected between the nozzle pack float and the horizontal plug rod assembly, and controls the opening range of the horizontal plug rod assembly according to the liquid level in the nozzle pack body 12, that is, the nozzle pack
  • the constant liquid level closed-loop control system is electrically connected between the nozzle pack float and the side plug rod 26 and controls the horizontal movement of the side plug rod 26.
  • the nozzle pack float is set as a float type liquid level sensor.
  • the nozzle pack constant liquid level closed-loop control system controls the side plug rod 26 to block the restrictor hole 22 or reduce the opening range.
  • the vacuum furnace The flow rate of molten steel at the outlet of the body 8 is reduced, and the molten iron in the vacuum furnace body 8 reduces the flow into the nozzle package body 12 through the water outlet of the vacuum furnace body 8.
  • the nozzle pack constant liquid level closed-loop control system controls the side plug rod 26 to increase the opening range.
  • the flow of molten iron at the outlet of the vacuum furnace body 8 increases, and the vacuum
  • the molten iron in the furnace body 8 flows into the nozzle package body 12 through the water outlet of the vacuum furnace body 8 to stably provide molten iron in the nozzle package body 12 and maintain the liquid level of the nozzle package body 12 constant, Realize the constant pressure spraying belt to maintain the consistency of the strip.
  • the nozzle pack float can also be replaced with other sensors with liquid level measurement functions, or other devices with specific liquid level measurement functions and capable of transmitting liquid level change signals to.
  • a nozzle plug rod 14 is detachably installed in the nozzle package body 12 corresponding to the water outlet of the nozzle package body 12, and a nozzle is installed at the bottom end of the nozzle package body 12 corresponding to the water outlet of the nozzle package body 12.
  • the nozzle corresponds to the crystallizer 3.
  • the horizontal plug rod assembly and The frame platform 1 is electrically connected with a vacuum furnace pouring opening and closing control system that controls the horizontal plug rod assembly to switch between the pouring state and the smelting state, and the side plug rod 26 is located at the right-angle liquid outlet part
  • the outer free end of 23 is also electrically connected to the pouring opening and closing control system of the vacuum furnace.
  • the horizontal plug rod assembly is always in a closed state, and the water outlet of the side bottom pouring steel device 11 is always kept in a closed state, and the molten steel in the vacuum furnace body 8 will not flow out; and when the vacuum furnace system
  • the vacuum furnace pouring opening and closing control system will control the nozzle package constant liquid level closed loop control system and the strip thickness constant closed loop control system to start working, and the nozzle package constant liquid level
  • the position closed-loop control system will control the movement of the horizontal plug rod assembly in real time, so as to control the opening and closing state of the water outlet of the side bottom steel pouring device 11, and adjust the opening and closing amplitude of the side plug 26
  • the flow rate of the molten iron is used to adjust the molten iron level in the nozzle pack 12 to maintain a constant height.
  • the closed-loop control system for the constant strip thickness will control the nozzle pack position adjustment mechanism 13 in real time to adjust the distance between the bottom nozzle of the nozzle pack body 12 and the upper cut surface
  • the nozzle is wrapped in the rod 14 is electrically connected to the frame platform 1 with a nozzle wrapper rod opening and closing control system that controls the nozzle wrapper rod 14 to switch between the spray band state and the non-spray band state; the nozzle wrapper rod 14
  • the opening and closing control system is also connected to the nozzle pack float and controls the nozzle pack rod 14 to rise and fall.
  • the nozzle pack rod opening and closing control system When the vacuum furnace system is at the smelting station, the nozzle pack rod opening and closing control system will control the nozzle pack constant liquid level closed loop control system and the strip thickness constant closed loop control system to stop working, and at the same time When the nozzle pack float monitors that the liquid level is less than the set value, the nozzle pack rod opening and closing control system will control the nozzle pack rod 14 to descend, and keep it in the descending state, and remove the nozzle pack body 12 The nozzle is always kept closed, and the molten steel in the nozzle package body 12 will not flow out.
  • the nozzle package body 12 is insulated and the nozzle can be replaced; when switched to the steel pouring station, the nozzle cover rod opens and closes
  • the control system first controls the nozzle pack constant liquid level closed-loop control system, raises the molten steel level in the nozzle pack body 12 to the spray band level, opens the nozzle pack lever 14 to continue spraying, and then controls all
  • the closed loop control system with constant strip thickness works normally.
  • the rack platform 1 is provided with a total automatic control system, the vacuum furnace system, the nozzle pack mechanism, the nozzle pack constant liquid level closed-loop control system, the crystallizer 3, the The automatic take-up device 4, the online thickness measurement device 5, the strip thickness constant closed-loop control system, the vacuum furnace pouring opening and closing control system, and the nozzle packing rod opening and closing control system are all electrically connected to the The total automatic control system; the total automatic control system realizes the fully automatic operation of this embodiment, saves time and effort, and is easy to operate.
  • Step 1 Refer to Figure 2. First, the vacuum furnace system melts the master alloy at the melting station and evacuates the slag to obtain a purified alloy steel;
  • Step 2 Then move the vacuum furnace system containing molten alloy steel to the pouring station through the walking rail 2, see Figure 1;
  • Step 3 Open the side plug rod 26, slowly pour the molten steel in the vacuum furnace body 8 into the nozzle package body 12 (at this time the nozzle package rod 14 is in the closed state), and establish a certain height Liquid level, and then close the side plug rod 26;
  • Step 4 After receiving the command from the spray belt staff to pour steel, open the nozzle cover rod 14 and the spray belt starts; after that, open the side stopper rod 26, and adjust the station in real time according to the nozzle bag float monitoring data.
  • Step 5 Monitor the strip thickness and deviation through the online thickness measuring device 5, adjust the front and rear, up and down, left and right and front and back tilt angles of the nozzle package 12 through the nozzle package position adjustment mechanism 13, and adjust the nozzle package in real time The distance between the nozzle at the bottom end of the body 12 and the crystallizer 3;
  • Step 6 After the vacuum furnace body 8 has finished pouring steel, close the side plug 26; the vacuum furnace system returns to the smelting station to continue smelting, see Figure 2;
  • Step 7 After the liquid level in the nozzle package body 12 is lower than the lowest set liquid level of the spray belt, close the nozzle package rod 14 and the nozzle package body 12 is insulated. At this time, the nozzle can be replaced; When steeling, after raising the liquid level of the molten steel in the nozzle package 12 to the level of the spray band, open the nozzle cover rod 14 to continue the spray band and start the reciprocating operation.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Refinement Of Pig-Iron, Manufacture Of Cast Iron, And Steel Manufacture Other Than In Revolving Furnaces (AREA)
  • Vertical, Hearth, Or Arc Furnaces (AREA)

Abstract

L'invention concerne un système de production de ruban nanocristallin à productivité élevée, lequel système comprend une plate-forme de bâti (1). Une piste mobile (2) est installée sur la plate-forme de bâti (1). Une position de travail de fusion et une position de travail de versement d'acier sont agencées au niveau de la piste mobile (2). Un système de four à vide est installé de manière coulissante au niveau de la piste mobile (2), et il effectue un mouvement de va-et-vient entre la position de travail de fusion et la position de travail de versement d'acier. Un mécanisme d'ensemble de buse correspondant au système de four à vide est disposé sous la plate-forme de bâti (1) dans une position correspondant à la position de travail de versement d'acier. Un système de commande de niveau de liquide constant d'ensemble de buse en boucle fermée est électriquement connecté entre le mécanisme d'ensemble de buse et le système de four à vide.
PCT/CN2019/095320 2019-05-17 2019-07-09 Système de production de ruban nanocristallin à productivité élevée WO2020232809A1 (fr)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
CN201910411891.2A CN110125353A (zh) 2019-05-17 2019-05-17 大容量纳米晶薄带生产系统
CN201910411891.2 2019-05-17

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WO2020232809A1 true WO2020232809A1 (fr) 2020-11-26

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