CN114769514B - Automatic continuous casting system - Google Patents

Abstract

The invention discloses an automatic continuous casting system, which comprises: the method comprises the steps of sand shell roasting, sand shell transferring and casting molding, and specifically comprises the following steps: s1, roasting a sand shell: heating the sand shell to more than 1000 ℃ in a roasting furnace by a mechanical arm; s2, transferring sand shells: after heating, sequentially taking the sand shells out of the roasting furnace through a mechanical arm, and placing the sand shells on a pouring station; s3, casting and forming: a weight sensor is arranged on the pouring station, molten iron is discharged for pouring when the weight sensor senses that the sand shell is in an empty sand shell state, and the molten iron is stopped from discharging after a certain weight is reached, so that the pouring is completed; the invention can accelerate the circulation of toxic gas in the electric furnace to the inside of the roasting furnace, so that the materials in the electric furnace react fully, and meanwhile, the inside of the roasting furnace is provided with a movable structure, so that the inside of the sand shell can be heated uniformly, impurities adhered to the inner wall of the roasting furnace can be removed, and the potential safety hazard problem in the following work is avoided.

Description

Automatic continuous casting system

Technical Field

The invention relates to the technical field of casting, in particular to an automatic continuous casting system.

Background

At present, industry rapidly develops, wherein an electric furnace and a roasting furnace take important roles in development, wherein the roasting furnace is a heating tool, the design and the technical advancement of the roasting furnace have great influence on the productivity, the energy consumption and the comprehensive utilization of energy of the quality unit investment of products, the service life of the furnace and the production cost of the products, the electric furnace liquefies metals and then casts, but the electric furnace works in such an environment, the safety of workers is not guaranteed, and with the continuous development of technology, the automation work is adopted for the most work, so that the working efficiency is improved, and the safety of the workers is also protected to a certain extent.

At present at the electric stove during operation, because the circulation of air in the electric stove is slower, lead to inside smog circulation slower, and smog has toxicity, influence staff's personal safety, and the inside material burning of calcination stove is insufficient, and because the temperature of each position is different, lead to slightly different in the heating condition of different positions, the inner wall of calcination stove can adhere to the waste material after the utilization simultaneously, lead to being heated unevenly, there is the potential safety hazard in the work that follows, simultaneously there is not sequential pouring work, influence work efficiency to a certain extent, in addition when the pouring, the pouring amount can't be controlled.

Disclosure of Invention

The invention aims to provide an automatic continuous casting system so as to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: an automated continuous casting method comprising: the method comprises the steps of sand shell roasting, sand shell transferring and casting molding, and specifically comprises the following steps:

s1, roasting a sand shell: heating the sand shell to more than 1000 ℃ in a roasting furnace by a mechanical arm;

s2, transferring sand shells: after heating, sequentially taking the sand shells out of the roasting furnace through a mechanical arm, and placing the sand shells on a pouring station;

S3, casting and forming: and a weight sensor is arranged on the pouring station, molten iron is discharged for pouring when the weight sensor senses that the sand shell is in an empty sand shell state, and the molten iron is stopped from discharging after a certain weight is reached, so that the pouring is completed.

Optionally, the order of placing the sand shells in the roasting furnace is as follows: the sand shell is taken out from the roasting furnace from inside to outside in the following sequence: from outside to inside.

The automatic continuous casting system comprises a manipulator body, wherein a workbench is arranged at the bottom of the manipulator body, an electric furnace body is arranged on the surface of the workbench, a roasting furnace component is movably arranged on one side of the electric furnace body, a fan component is movably arranged at the top of the electric furnace body, and a power component is movably arranged at the bottom of the roasting furnace component.

Optionally, the inside of electric stove body is provided with interior stove, be provided with the clearance between the inner wall of electric stove body and the interior stove, the top of electric stove body is provided with the logical groove with fan assembly swing joint.

Optionally, the roasting furnace assembly includes the roasting furnace body of being connected with the workstation, the inside activity of roasting furnace body is provided with the movable furnace, the inside of movable furnace is provided with a plurality of storage racks, one side surface intercommunication of roasting furnace body is provided with first air duct, the bottom of roasting furnace body is provided with the filter, be provided with the space between roasting furnace body and the movable furnace, the surface of storage rack is provided with a plurality of recesses that are used for placing the sand shell.

Optionally, the fan assembly includes the first motor case of being connected with the electric stove body, the output of first motor case is provided with the flabellum with electric stove body swing joint, one side intercommunication of electric stove body is provided with the second air duct, the surface of second air duct and first air duct all is provided with control valve.

Optionally, the power component includes the second motor case of being connected with the workstation, the output of second motor case runs through the inner wall of roasting furnace body, just the output of second motor case is provided with the rotary disk, the output of second motor case is connected with the storage rack.

Optionally, the surface activity of activity stove is provided with a plurality of loose axles, the surface of loose axle is provided with a plurality of scrapers, even and certain distance setting between the loose axle is adjacent, the scraper blade laminating sets up the surface at the activity stove, the inner wall of roasting stove body is provided with two protruding pieces, two the certain distance setting between the protruding piece, just protruding piece and scraper blade swing joint are in the same place.

Optionally, one end of the second air duct penetrates through the inner wall of the roasting furnace body, the second air duct is communicated with a lower gap of the filter plate, and one end of the first air duct is communicated with an upper gap of the filter plate.

Optionally, when the movable furnace is movably connected with the roasting furnace body, when the movable shaft rotates along with the movable furnace, the scraping plate is movably extruded and connected with the protruding block, and the scraping plate is movably extruded on the surface of the movable furnace through the protruding block.

Compared with the prior art, the invention has the beneficial effects that:

The inside of putting into electric stove body with the material is processed, then put into movable stove inside with the sand shell through the manipulator body, place the sand shell in the storage rack corresponding position through the manipulator body, process simultaneously, then open first motor case work, the output of first motor case drives the flabellum work, the flabellum rotates the inside air flow of accelerating electric stove body, move the inside of roasting stove body with toxic smog in order through the second air duct, through the filtering capability of filter, can filter the smog that has impurity with inside the electric stove body, the gas after the filtration will make the inside material reaction of roasting stove body more abundant, the same improvement work efficiency, avoid poisonous gas to influence staff's personal safety simultaneously.

The second motor case starts, and the output shaft of second motor case drives the movable furnace and rotates, drives the loose axle and rotates when the movable furnace rotates, and the loose axle drives the scraper blade to rotate, and when the scraper blade rotates, scraper blade and projection extrusion activity because the setting that falls staggeredly between the scraper blade can clear up the impurity of movable furnace inner wall adhesion, avoids everywhere temperature difference, and at this moment, because the movable furnace drives the storage rack rotation, can be with the storage rack even that is heated, avoids appearing the potential safety hazard problem in the work that follows.

The sand shell is regularly fetched and placed, the fetching and placing sequence is prevented from being disordered, partial sand shell is not fully heated, the heating effect of the sand shell is good, the manipulator body works through the track, the working efficiency is improved to a certain extent, in addition, the pouring flow can be controlled through the weight sensor arranged on the station, and the obtained pouring product is better in quality.

Drawings

FIG. 1 is a system step diagram of an automated continuous casting system of the present invention;

FIG. 2 is a schematic diagram of the overall structure of an automated continuous casting system according to the present invention;

FIG. 3 is a schematic view of a part of an automated continuous casting system according to the present invention;

FIG. 4 is a partial cross-sectional view of one of the automated continuous casting systems of the present invention;

FIG. 5 is a partial cross-sectional view of an automated continuous casting system of the present invention;

fig. 6 is a partial cross-sectional view of an automated continuous casting system according to the present invention.

In the figure: 1. a work table; 2. a robot body; 3. an electric furnace body; 4. a calciner assembly; 41. a roasting furnace body; 42. a movable furnace; 43. a storage rack; 44. a first air duct; 45. a filter plate; 5. a fan assembly; 51. a first motor case; 52. a fan blade; 53. a second air duct; 54. a control valve; 6. a power assembly; 61. a second motor case; 62. a rotating disc; 63. a movable shaft; 64. a scraper; 65. and (5) a protruding block.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1 to 6, the present invention provides an automated continuous casting method, comprising: the method comprises the steps of sand shell roasting, sand shell transferring and casting molding, and specifically comprises the following steps:

s1, roasting a sand shell: heating the sand shell to more than 1000 ℃ in a roasting furnace by a mechanical arm;

s2, transferring sand shells: after heating, sequentially taking the sand shells out of the roasting furnace through a mechanical arm, and placing the sand shells on a pouring station;

S3, casting and forming: and a weight sensor is arranged on the pouring station, molten iron is discharged for pouring when the weight sensor senses that the sand shell is in an empty sand shell state, and the molten iron is stopped from discharging after a certain weight is reached, so that the pouring is completed.

Wherein, the order of sand shell in the roasting furnace is: the sand shell is taken out from the roasting furnace from inside to outside in the following sequence: the sand shells are regularly taken and placed from outside to inside, so that the condition that the taking and placing sequence is disordered and the heating of part of the sand shells is insufficient is avoided.

As shown in fig. 2, an automatic continuous casting system is applied to the automatic continuous casting method, and comprises a manipulator body 2, wherein a workbench 1 is arranged at the bottom of the manipulator body 2, an electric furnace body 3 is arranged on the surface of the workbench 1, a roasting furnace component 4 is movably arranged on one side of the electric furnace body 3, a fan component 5 is movably arranged at the top of the electric furnace body 3, and a power component 6 is movably arranged at the bottom of the roasting furnace component 4.

The inside of electric stove body 3 is provided with interior stove, be provided with the clearance between the inner wall of electric stove body 3 and the interior stove, the top of electric stove body 3 is provided with the logical groove with fan assembly 5 swing joint, drive the inside circulation of air of electric stove body 3 through fan assembly 5, make the material react fully, place the inside at roasting furnace assembly 4 with the sand shell is orderly through manipulator body 2, then move the inside to roasting furnace assembly 4 through fan assembly 5 with the air, improve work efficiency equally, drive the activity of roasting furnace assembly 4 through power assembly 6, be heated evenly with the inside sand shell of roasting furnace assembly 4.

As shown in fig. 2 and 4, the roasting furnace assembly 4 comprises a roasting furnace body 41 connected with the workbench 1, a movable furnace 42 is movably arranged in the roasting furnace body 41, a plurality of storage racks 43 are arranged in the movable furnace 42, a first air duct 44 is arranged on one side surface of the roasting furnace body 41 in a communicated manner, a filter plate 45 is arranged at the bottom of the roasting furnace body 41, a gap is arranged between the roasting furnace body 41 and the movable furnace 42, a plurality of grooves for placing sand shells are arranged on the surface of the storage racks 43, the sand shells orderly placed on the surface of the storage racks 43 can be heated uniformly by moving the movable furnace 42 in the roasting furnace body 41, air can be discharged through the first air duct 44, impurities in the air can be filtered by the filter plate 45, and the air can be prevented from being discharged.

As shown in fig. 3, 4 and 6, the fan assembly 5 includes a first motor case 51 connected to the electric furnace body 3, a fan blade 52 movably connected to the electric furnace body 3 is disposed at an output end of the first motor case 51, a second air duct 53 is disposed on one side of the electric furnace body 3 in a communicating manner, control valves 54 are disposed on surfaces of the second air duct 53 and the first air duct 44, the fan blade 52 is driven to rotate by the first motor case 51, air inside the electric furnace body 3 can be driven to circulate, and then air is flowed into the roasting furnace assembly 4 by the second air duct 53, and the magnitude of the air circulation is controlled by the control valves 54.

As shown in fig. 4 and 5, the power assembly 6 includes a second motor case 61 connected to the workbench 1, an output end of the second motor case 61 penetrates through an inner wall of the roasting furnace body 41, and an output end of the second motor case 61 is connected to the storage rack 43, and drives the rotary disk 62 to rotate through the second motor case 61, and drives the movable furnace 42 to rotate through the rotary disk 62.

As shown in fig. 4 and fig. 5, the surface of the movable furnace 42 is movably provided with a plurality of movable shafts 63, the surface of the movable shaft 63 is provided with a plurality of scrapers 64, the movable shafts 63 are arranged uniformly and at a certain distance from each other, the scrapers 64 are attached to the surface of the movable furnace 42, two protruding blocks 65 are arranged on the inner wall of the roasting furnace body 41, the two protruding blocks 65 are arranged at a certain distance from each other, the protruding blocks 65 are movably connected with the scrapers 64, the movable shaft 63 is driven to rotate when the movable furnace 42 rotates, the movable shaft 63 drives the scrapers 64 to rotate, the scrapers 64 are extruded with the protruding blocks 65 when rotating, so that the scrapers 64 rotate, impurities on the surface of the movable furnace 42 are removed when the scrapers 64 rotate, and the problem of overlarge temperature difference is avoided.

As shown in fig. 3 and 4, one end of the second air duct 53 penetrates through the inner wall of the roasting furnace body 41, the second air duct 53 is communicated with the lower space of the filter plate 45, one end of the first air duct 44 is communicated with the upper space of the filter plate 45, and air is moved from the interior of the electric furnace body 3 to the interior of the roasting furnace body 41 through the second air duct 53, so that air circulation is quickened, and meanwhile, the working efficiency is improved.

As shown in fig. 4 and 5, when the movable furnace 42 is movably connected with the roasting furnace body 41, the movable shaft 63 is movably connected with the protruding block 65 when the movable shaft 63 rotates along with the movable furnace 42, the scraper 64 is movably extruded and connected with the protruding block 65, the scraper 64 is movably extruded on the surface of the movable furnace 42 through the protruding block 65, the movable shaft 63 is driven to rotate while the movable furnace 42 rotates, the scraper 64 is driven to rotate by the movable shaft 63, and the scraper 64 and the protruding block 65 are extruded to move while the scraper 64 rotates, so that impurities adhered to the inner wall of the movable furnace 42 can be cleaned due to the staggered arrangement between the scrapers 64.

Working principle: when the device works, materials are placed into the electric furnace body 3 for processing, then sand shells are placed into the movable furnace 42 through the manipulator body 2, the sand shells are placed at corresponding positions of the storage racks 43 for processing simultaneously, then the first motor box 51 is opened for working, the output end of the first motor box 51 drives the fan blades 52 to work, the fan blades 52 rotate to quicken the air flow in the electric furnace body 3, toxic smoke is orderly moved into the roasting furnace body 41 through the second air guide pipe 53, the smoke with impurities in the electric furnace body 3 can be filtered through the filtering function of the filtering plate 45, the filtered air can enable the materials in the roasting furnace body 41 to react more fully, the work efficiency is improved equally, avoid poisonous gas to influence staff's personal safety, simultaneously, second motor case 61 starts, the output shaft of second motor case 61 drives movable stove 42 and rotates, drive movable shaft 63 and rotate when movable stove 42 rotates, movable shaft 63 drives scraper blade 64 and rotates, scraper blade 64 and protruding piece 65 extrusion activity when scraper blade 64 rotates, because the setting of staggering between scraper blade 64, can clear away the impurity of movable stove 42 inner wall adhesion, avoid everywhere temperature difference, at this moment, because movable stove 42 drives storage rack 43 rotation, can be with storage rack 43 even being heated, avoid appearing the potential safety hazard problem in the work that follows.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. An automated coherent pouring system, characterized in that the pouring method applying the system comprises: the method comprises the steps of sand shell roasting, sand shell transferring and casting molding, and specifically comprises the following steps:

s1, roasting a sand shell: heating the sand shell to more than 1000 ℃ in a roasting furnace by a mechanical arm;

s2, transferring sand shells: after heating, sequentially taking the sand shells out of the roasting furnace through a mechanical arm, and placing the sand shells on a pouring station;

s3, casting and forming: a weight sensor is arranged on the pouring station, molten iron is discharged for pouring when the weight sensor senses that the sand shell is empty, and the molten iron is stopped from discharging after a certain weight is reached, so that the pouring is completed;

The order of placing the sand shells in the roasting furnace is as follows: the sand shell is taken out from the roasting furnace from inside to outside in the following sequence: from outside to inside;

The manipulator in the step S1 comprises a manipulator body (2), wherein a workbench (1) is arranged at the bottom of the manipulator body (2), an electric furnace body (3) is arranged on the surface of the workbench (1), a roasting furnace component (4) is movably arranged on one side of the electric furnace body (3), a fan component (5) is movably arranged at the top of the electric furnace body (3), and a power component (6) is movably arranged at the bottom of the roasting furnace component (4); the roasting furnace assembly (4) comprises a roasting furnace body (41) connected with a workbench (1), a movable furnace (42) is movably arranged in the roasting furnace body (41), a plurality of storage racks (43) are arranged in the movable furnace (42), a first air duct (44) is arranged on one side surface of the roasting furnace body (41) in a communicated mode, a filter plate (45) is arranged at the bottom of the roasting furnace body (41), a gap is formed between the roasting furnace body (41) and the movable furnace (42), and a plurality of grooves used for placing sand shells are formed in the surface of the storage racks (43); the surface of the movable furnace (42) is movably provided with a plurality of movable shafts (63), the surface of the movable shafts (63) is provided with a plurality of scraping plates (64), the movable shafts (63) are arranged evenly and at a certain distance between adjacent positions, the scraping plates (64) are attached to the surface of the movable furnace (42), the inner wall of the roasting furnace body (41) is provided with two protruding blocks (65), the two protruding blocks (65) are arranged at a certain distance, and the protruding blocks (65) are movably connected with the scraping plates (64); when the movable furnace (42) is movably connected with the roasting furnace body (41), the movable shaft (63) rotates along with the movable furnace (42), the scraping plate (64) is movably extruded and connected with the protruding block (65), and the scraping plate (64) is movably extruded on the surface of the movable furnace (42) through the protruding block (65).

2. An automated continuous casting system according to claim 1, characterized in that an inner furnace is arranged inside the electric furnace body (3), a gap is arranged between the inner wall of the electric furnace body (3) and the inner furnace, and a through groove movably connected with the fan assembly (5) is arranged at the top of the electric furnace body (3).

3. An automated continuous casting system according to claim 2, characterized in that the fan assembly (5) comprises a first motor box (51) connected with the electric furnace body (3), the output end of the first motor box (51) is provided with a fan blade (52) movably connected with the electric furnace body (3), one side of the electric furnace body (3) is communicated with a second air duct (53), and the surfaces of the second air duct (53) and the first air duct (44) are both provided with a control valve (54).

4. An automated continuous casting system according to claim 3, characterized in that the power assembly (6) comprises a second motor box (61) connected to the table (1), the output end of the second motor box (61) penetrating the inner wall of the roasting furnace body (41), and the output end of the second motor box (61) being provided with a rotating disc (62), the output end of the second motor box (61) being connected to the storage rack (43).

5. An automated continuous casting system according to claim 4, wherein one end of the second air duct (53) penetrates through the inner wall of the roasting furnace body (41), the second air duct (53) is communicated with the lower space of the filter plate (45), and one end of the first air duct (44) is communicated with the upper space of the filter plate (45).