CN210280596U - Silver ingot automatic casting equipment - Google Patents

Abstract

The utility model provides an automatic silver ingot casting device, which comprises a lifting platform and a casting device arranged on the top surface of the lifting platform, wherein one side of the lifting platform is provided with a mould moving device, and the mould moving device is provided with a plurality of weighing sensors used for measuring the total weight of the mould moving device; the casting device comprises a rack and an intermediate frequency furnace, wherein a crucible is arranged on one side of the rack close to the mold moving device, the crucible is arranged on the rack through a casting mechanism, and the casting mechanism is used for pushing and dumping the crucible; a first distance measuring sensor is erected above the crucible, a second distance measuring sensor is erected on one side of the mold moving device and located above the moving track of the mold car, and the second distance measuring sensor and the liquid outlet of the crucible are located on the same vertical plane; the utility model aims to solve the technical problem that a silver ingot automatic casting equipment is proposed, it can realize automatic casting, and casting amount control precision is high, can effectively improve product quality.

Description

Silver ingot automatic casting equipment

Technical Field

The utility model relates to a silver ingot casting equipment field, more specifically relates to a silver ingot automatic casting equipment.

Background

The silver ingot casting mainly comprises two modes of manual casting and mechanical casting.

Manual casting: the intermediate frequency furnace melts the silver into a molten liquid state and removes oxygen, the crucible is lifted and transported to a casting area by a set of simple lifting appliance manually, and the lifting casting is carried out manually.

Mechanical casting: the intermediate frequency furnace is manually controlled to remove oxygen and pour molten silver liquid into a casting crucible by adopting a remote controller or a button on an operation panel (platform) and the like, then the casting crucible is sequentially cast into a vertical mold cavity, and the casting amount is inching controlled by manually operating the button.

The silver liquid has higher heat conductivity coefficient and is condensed very quickly, so that an operator needs to have very high reaction speed in the manual casting process, and once the operation has slight deviation, the waste ingot is likely to be cast, and the physical consumption of the operator is large; in addition, mechanical casting is difficult in controlling the casting amount of the casting liquid, and the casting amount is often too large or too small, so that the weight of the cast silver ingot does not reach the standard, and waste products are generated.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects of the prior art, the utility model aims to solve the technical problem that a silver ingot automatic casting equipment is provided, its novel structure can realize automatic casting, and casting quantity control precision is high, can effectively improve product quality.

To achieve the purpose, the utility model adopts the following technical proposal:

the utility model provides an automatic silver ingot casting device, including elevating platform and locate the casting device of elevating platform top surface, one side of elevating platform is equipped with mould mobile device, mould mobile device includes first guide rail seat and locates the mould car on the first guide rail seat, the mould car slides along the first guide rail seat under the drive of lead screw actuating mechanism, be equipped with a plurality of weighing sensor that are used for measuring the mould mobile device total weight on the first guide rail seat, be equipped with a plurality of forming die on the mould car, a plurality of forming die is along the linear array distribution of mould car moving direction;

the casting device comprises a rack and an intermediate frequency furnace fixedly arranged on the rack, the rack is fixedly arranged on the top surface of the lifting table, a crucible is arranged on one side, close to the mold moving device, of the rack, the crucible is positioned below a liquid discharge port of the intermediate frequency furnace, the liquid discharge port of the crucible is positioned above the forming mold, the crucible is arranged on the rack through a casting mechanism, and the casting mechanism is used for pushing and dumping the crucible; the top of crucible is equipped with first range sensor through the strut frame, first range sensor's probe orientation the top surface of crucible, one side of mould mobile device is equipped with second range sensor through the strut frame, second range sensor is located the top of the removal orbit of mould car, second range sensor's probe sets up down, just second range sensor with the leakage fluid dram of crucible is in same vertical plane.

In the preferred technical solution of the present invention, the casting mechanism includes a mounting frame, one side of the mounting frame near the frame is fixedly connected to the frame by screws, the other side of the mounting frame is fixedly provided with two oppositely disposed mounting raised bars, a guide slide bar is fixed above the top surface of each of the two mounting raised bars, a slider is slidably disposed on each guide slide bar, one side of each guide slide bar is respectively provided with a first hydraulic cylinder, the end of a piston rod of each first hydraulic cylinder is fixedly connected to the corresponding slider by a connecting member, and the two first hydraulic cylinders are both mounted on the mounting frame;

one of the two sliding blocks is provided with a bearing seat, the other sliding block is provided with a first motor, the crucible is positioned between the two sliding blocks, pin shafts are fixedly arranged on two opposite sides of the crucible, one pin shaft is rotatably connected with the bearing seat, and the other pin shaft is in transmission connection with an output shaft of the first motor through a first speed reducer.

In the preferred technical solution of the present invention, the first guide rail seat is provided with two parallel first guide rail protruding bars and a plurality of first connecting plates for connecting and fixing the two first guide rail protruding bars, the bottom of the mold car is provided with a plurality of first wheels corresponding to the two first guide rail protruding bars, and the mold car moves along the first guide rail protruding bars via the first wheels;

the lead screw drive mechanism comprises a lead screw, the lead screw is parallel to the first guide rail raised line, the lead screw is installed below the die car through two bearing seats, the lead screw sleeve is provided with an edge, the slide is moved by the lead screw, the top surface of the slide is fixedly connected with the top surface of the die car, one end of the lead screw is connected with an output shaft of the second motor through a coupler, and the second motor is installed on the first guide rail seat.

The utility model discloses in the technical scheme of preferred, weighing sensor fixed mounting is in the bottom surface of first connecting plate, it is a plurality of weighing sensor is right the mould mobile device forms built on stilts support.

In the preferred technical solution of the present invention, a frame for placing the forming mold is provided on the top surface of the mold carriage, and a plurality of forming molds are erected on the frame and distributed in a linear array along the moving direction of the mold carriage; and a second hydraulic cylinder is fixedly mounted at one end of the frame, one end of a piston rod of the second hydraulic cylinder faces to the center direction of the frame, and the second hydraulic cylinder is used for clamping and fixing the forming die.

In the preferred technical solution of the present invention, a second guide rail seat is disposed below the lifting platform, the second guide rail seat is provided with two second guide rail protruding bars parallel to each other and a second connecting plate for connecting and fixing the two second guide rail protruding bars, the length direction of the two second guide rail protruding bars is perpendicular to the moving direction of the mold carriage, a plurality of second wheels are mounted on the bottom surface of the lifting platform corresponding to the two second guide rail protruding bars, and the lifting platform moves along the second guide rail protruding bars through the second wheels; the two second wheels which are arranged oppositely are connected through a transmission rod, one end of the transmission rod is in transmission connection with an output shaft of a third motor through a second speed reducer, and the third motor is installed at the bottom of the lifting platform.

The utility model discloses in the technical scheme of preferred, first range finding sensor reaches second range finding sensor is laser distance measuring sensor.

The utility model discloses among the technical scheme of preferred, the below of mould car is equipped with accepts the groove, it is located two to accept the groove between the first guide rail sand grip, it follows to accept the groove the removal orbit setting of mould car.

The utility model has the advantages that:

the utility model provides an automatic silver ingot casting device, which has novel structure and can realize automatic casting, casting liquid in an intermediate frequency furnace is poured into a crucible, the liquid level in the crucible is measured through a first distance measuring sensor, and when the liquid level reaches a set value, the intermediate frequency furnace stops inputting the casting liquid into the crucible; the positions of the forming die and a casting opening of the crucible are detected through a second distance measuring sensor, and when the alignment is accurate, the crucible is pushed and poured through a casting mechanism, so that casting liquid accurately enters the forming die; when the weighing sensor detects that the casting quantity reaches a preset value, the crucible is straightened and no casting is carried out; the automatic casting of all the forming molds is completed under the coordination of all the parts, the control precision of the casting amount is high, and the product quality can be effectively improved.

Drawings

Fig. 1 is a schematic perspective view of an automatic silver ingot casting apparatus according to an embodiment of the present invention;

fig. 2 is a schematic view of a first perspective three-dimensional structure of a mold moving mechanism provided in an embodiment of the present invention;

fig. 3 is a schematic view of a second perspective three-dimensional structure of a mold moving mechanism provided in an embodiment of the present invention;

FIG. 4 is an enlarged view of portion A of FIG. 3;

fig. 5 is a schematic perspective view of a mold carriage provided in an embodiment of the present invention;

fig. 6 is a schematic perspective view of a casting device provided in an embodiment of the present invention;

fig. 7 is a schematic perspective view of a casting mechanism provided in an embodiment of the present invention.

In the figure:

100. a lifting platform; 110. a second wheel; 120. a transmission rod; 130. a third motor; 140. a second decelerator; 200. a casting device; 210. a frame; 220. an intermediate frequency furnace; 230. a crucible; 300. a mold moving device; 310. a first guide rail seat; 311. a first rail rib; 312. a first connecting plate; 320. carrying out mould turning; 321. a first wheel; 322. a frame; 330. a lead screw drive mechanism; 331. a lead screw; 332. a slide base; 333. a second motor; 340. a weighing sensor; 350. forming a mold; 360. a second hydraulic cylinder; 400. a casting mechanism; 410. a mounting frame; 420. installing convex strips; 430. a guide slide bar; 440. a slider; 450. a first hydraulic cylinder; 460. a first motor; 470. a first decelerator; 510. a first ranging sensor; 520. a second ranging sensor; 610. a second rail seat; 611. a second rail rib; 612. a second connecting plate; 700. a receiving groove.

Detailed Description

The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.

As shown in fig. 1, the embodiment of the present invention discloses an automatic silver ingot casting apparatus, including a lifting table 100 and a casting device 200 disposed on the top surface of the lifting table 100, one side of the lifting table 100 is provided with a mold moving device 300, as shown in fig. 2 to 4, the mold moving device 300 includes a first guide rail seat 310 and a mold carriage 320 disposed on the first guide rail seat 310, the mold carriage 320 slides along the first guide rail seat 310 under the driving of a lead screw driving mechanism 330, the first guide rail seat 310 is provided with a plurality of weighing sensors 340 for measuring the total weight of the mold moving device 300, the mold carriage 320 is provided with a plurality of forming molds 350, and the plurality of forming molds 350 are distributed in a linear array along the moving direction of the mold carriage 320;

as shown in fig. 6, the casting device 200 includes a frame 210 and an intermediate frequency furnace 220 fixedly disposed on the frame 210, the frame 210 is fixedly mounted on the top surface of the lifting table 100, a crucible 230 is disposed on a side of the frame 210 close to the mold moving device 300, the crucible 230 is located below a drain outlet of the intermediate frequency furnace 220, the drain outlet of the crucible 230 is located above the forming mold 350, the crucible 230 is mounted on the frame 210 through a casting mechanism 400, and the casting mechanism 400 is used for pushing and tilting the crucible 230; first distance measuring sensor 510 is erected through the strut in the top of crucible 230, first distance measuring sensor 510's probe orientation the top surface of crucible 230, one side of mould mobile device 300 is erected through the strut and is equipped with second distance measuring sensor 520, second distance measuring sensor 520 is located the top of the removal orbit of mould car 320, second distance measuring sensor 520's probe sets up down, just second distance measuring sensor 520 with crucible 230's drain outlet is in same vertical plane.

The automatic silver ingot casting equipment is novel in structure and can realize automatic casting, casting liquid in the intermediate frequency furnace 220 is poured into the crucible 230, the liquid level in the crucible 230 is measured through the first distance measuring sensor 510, and when the liquid level reaches a set value, the intermediate frequency furnace 220 stops inputting the casting liquid into the crucible 230; the positions of the casting gates of the forming mold 350 and the crucible 230 are detected by the second distance measuring sensor 520, and when the alignment is accurate, the crucible 230 is pushed and poured by the casting mechanism 400, so that the casting liquid accurately enters the forming mold 350; when the weighing sensor 340 detects that the casting amount reaches a preset value, the crucible 230 is straightened and is not cast any more; the automatic casting of all the forming molds 350 is completed under the coordination of all the parts, the control precision of the casting amount is high, and the product quality can be effectively improved.

Further, as shown in fig. 7, the casting mechanism 400 includes a mounting frame 410, one side of the mounting frame 410 close to the rack 210 is fixedly connected to the rack 210 through a screw, the other side of the mounting frame 410 is fixedly provided with two opposite mounting protruding strips 420, guide sliding rods 430 are fixedly arranged above top surfaces of the two mounting protruding strips 420, each guide sliding rod 430 is slidably provided with a sliding block 440, one side of each guide sliding rod 430 is respectively provided with a first hydraulic cylinder 450, a piston rod end of each first hydraulic cylinder 450 is fixedly connected to the corresponding sliding block 440 through a connecting member, and both first hydraulic cylinders 450 are mounted on the mounting frame 410;

one of the sliding blocks 440 is provided with a bearing seat, the other sliding block 440 is provided with a first motor 460, the crucible 230 is positioned between the two sliding blocks 440, two opposite sides of the crucible 230 are fixedly provided with a pin shaft, one of the pin shafts is rotatably connected with the bearing seat, and the other pin shaft is in transmission connection with an output shaft of the first motor 460 through a first speed reducer 470.

When the casting mechanism 400 pushes and pours the crucible 230, firstly, the piston rods of the two first hydraulic cylinders 450 extend to push the crucible 230 toward the mold moving device 300, after the crucible 230 is moved to a preset position, the first motor 460 is started to drive the crucible 230 to pour, the casting liquid in the crucible 230 is injected into the forming mold 350, and when the weighing sensor 340 detects that the casting amount of one-time casting reaches a preset value, the first motor 460 rotates reversely, the crucible 230 swings right, and the first hydraulic cylinders 450 are reset to complete the casting of one forming mold 350; wherein the load cell 340 is required to a C6 level accuracy.

Further, as shown in fig. 3 and 4, the first rail seat 310 is provided with two first rail protruding strips 311 parallel to each other and a plurality of first connecting plates 312 for connecting and fixing the two first rail protruding strips 311, a plurality of first wheels 321 are installed at the bottom of the mold carriage 320 corresponding to the two first rail protruding strips 311, and the mold carriage 320 moves along the first rail protruding strips 311 via the first wheels 321;

lead screw actuating mechanism 330 includes lead screw 331, lead screw 331 with first guide rail sand grip 311 is parallel, lead screw 331 is installed through two bearing housing the below of mould car 320, lead screw 331 cover is equipped with the edge slide 332 that lead screw 331 removed, slide 332's top surface with the top surface fixed connection of mould car 320, the one end of lead screw 331 passes through the coupling joint with the output shaft of second motor 333, second motor 333 installs on first guide rail housing 310.

The first guide rail convex strip 311 and the first wheel 321 are matched to limit the moving track of the mold carriage 320, so that the molding mold 350 and the sprue gate of the crucible 230 can be accurately aligned; the lead screw driving mechanism 330 is provided to facilitate stable movement of the mold carriage 320.

Further, the load cells 340 are fixedly installed on the bottom surface of the first connection plate 312, and the plurality of load cells 340 form an overhead support for the mold moving device 300.

Further, as shown in fig. 5, a frame 322 for placing the forming mold 350 is provided on the top surface of the mold carriage 320, and a plurality of forming molds 350 are erected on the frame 322 and distributed in a linear array along the moving direction of the mold carriage 320; frame 322's one end fixed mounting has second pneumatic cylinder 360, the piston rod one end orientation of second pneumatic cylinder 360 the center direction of frame 322, second pneumatic cylinder 360 is used for the centre gripping, fixes forming die 350.

The frame 322 and the design of the second hydraulic cylinder 360 can facilitate the placement and fixation of the forming mold 350, prevent the loosening in the moving process of the mold carriage 320, and avoid the problem of the forming mold 350 in the alignment to influence the normal casting.

Further, as shown in fig. 6, a second rail seat 610 is disposed below the lifting platform 100, the second rail seat 610 is provided with two second rail protruding strips 611 parallel to each other, and a second connecting plate 612 for connecting and fixing the two second rail protruding strips 611, a length direction of the two second rail protruding strips 611 is perpendicular to a moving direction of the mold carriage 320, a plurality of second wheels 110 are mounted on a bottom surface of the lifting platform 100 corresponding to the two second rail protruding strips 611, and the lifting platform 100 moves along the second rail protruding strips 611 through the second wheels 110; two oppositely arranged second wheels 110 are connected through a transmission rod 120, one end of the transmission rod 120 is in transmission connection with an output shaft of a third motor 130 through a second reducer 140, and the third motor 130 is installed at the bottom of the lifting platform 100.

The second rail seat 610 and the second wheel 110 are designed to facilitate the movement of the lifting platform 100, and the driving power for the movement is provided by the third motor 130.

Further, the first distance measuring sensor 510 and the second distance measuring sensor 520 are both laser distance measuring sensors; the laser ranging sensor can greatly improve the detection precision, and the German SICK DT1000 laser ranging sensor is preferably selected.

Further, a receiving groove 700 is arranged below the mold carriage 320, the receiving groove 700 is located between the two first guide rail convex strips 311, and the receiving groove 700 is arranged along the moving track of the mold carriage 320; the receiving groove 700 is designed to receive the casting liquid dropped from the forming mold 350, so that waste is reduced.

The working principle is as follows:

when the silver ingot casting device is used for silver ingot casting, the second motor 333 is started firstly, the second motor 333 drives the mold trolley 320 to move, and when the second distance measuring sensor 520 detects that the forming mold 350 moves to a set position, the second motor 333 stops rotating; then, the intermediate frequency furnace 220 conveys the casting liquid to the crucible 230, and when the first distance measuring sensor 510 detects that the liquid level of the casting liquid in the crucible 230 reaches a preset value, the intermediate frequency furnace 220 stops conveying the casting liquid to the crucible 230; then the first hydraulic cylinder 450 is started, the first hydraulic cylinder 450 pushes the crucible 230 in a direction close to the forming mold 350, when the crucible 230 moves to a set position, the pouring gate of the crucible 230 is aligned with the forming mold 350, the first motor 460 is started, the first motor 460 drives the crucible 230 to pour, the casting liquid in the crucible 230 is accurately poured into the forming mold 350, when the weighing sensor 340 detects that the casting amount reaches a preset value, the first motor 460 drives the crucible 230 to swing right and stop casting, and the first hydraulic cylinder 450 resets; then, the second motor 333 is started to drive the mold carriage 320 to move, the above-mentioned process is repeated, the intermediate frequency furnace 220 conveys the casting liquid to the crucible 230, the crucible 230 casts to the forming mold 350, and the casting is completed on all the forming molds 350.

While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the spirit and scope of the invention. The present invention is not to be limited by the specific embodiments disclosed herein, and other embodiments that fall within the scope of the claims of the present application are intended to be within the scope of the present invention.

Claims (8)

1. The utility model provides a silver ingot automatic casting equipment which characterized in that:

the casting device comprises a lifting platform (100) and a casting device (200) arranged on the top surface of the lifting platform (100), wherein a mold moving device (300) is arranged on one side of the lifting platform (100), the mold moving device (300) comprises a first guide rail seat (310) and a mold carriage (320) arranged on the first guide rail seat (310), the mold carriage (320) slides along the first guide rail seat (310) under the drive of a lead screw driving mechanism (330), a plurality of weighing sensors (340) used for measuring the total weight of the mold moving device (300) are arranged on the first guide rail seat (310), a plurality of forming molds (350) are arranged on the mold carriage (320), and the plurality of forming molds (350) are distributed in a linear array along the moving direction of the mold carriage (320);

the casting device (200) comprises a rack (210) and an intermediate frequency furnace (220) fixedly arranged on the rack (210), the rack (210) is fixedly arranged on the top surface of the lifting table (100), a crucible (230) is arranged on one side, close to the mold moving device (300), of the rack (210), the crucible (230) is positioned below a liquid discharge port of the intermediate frequency furnace (220), the liquid discharge port of the crucible (230) is positioned above the forming mold (350), the crucible (230) is arranged on the rack (210) through a casting mechanism (400), and the casting mechanism (400) is used for pushing and dumping the crucible (230); the top of crucible (230) is equipped with first range sensor (510) through the strut frame, the probe orientation of first range sensor (510) the top surface of crucible (230), one side of mould mobile device (300) is equipped with second range sensor (520) through the strut frame, second range sensor (520) are located the top of the removal orbit of mould car (320), the probe of second range sensor (520) sets up down, just second range sensor (520) with the leakage fluid dram of crucible (230) is in same vertical plane.

2. The automatic silver ingot casting device according to claim 1, wherein:

the casting mechanism (400) comprises a mounting frame (410), one side, close to the rack (210), of the mounting frame (410) is fixedly connected with the rack (210) through screws, two opposite mounting convex strips (420) are fixedly arranged on the other side of the mounting frame (410), guide slide bars (430) are fixedly arranged above the top surfaces of the two mounting convex strips (420), sliding blocks (440) are arranged on the guide slide bars (430) in a sliding mode, first hydraulic cylinders (450) are respectively arranged on one sides of the guide slide bars (430), the end portions of piston rods of the first hydraulic cylinders (450) are fixedly connected with the corresponding sliding blocks (440) through connecting pieces, and the two first hydraulic cylinders (450) are mounted on the mounting frame (410);

one of the two sliding blocks (440) is provided with a bearing seat, the other sliding block (440) is provided with a first motor (460), the crucible (230) is positioned between the two sliding blocks (440), pin shafts are fixedly arranged on two opposite sides of the crucible (230), one of the pin shafts is rotatably connected with the bearing seat, and the other pin shaft is in transmission connection with an output shaft of the first motor (460) through a first speed reducer (470).

3. The automatic silver ingot casting device according to claim 1, wherein:

the first guide rail seat (310) is provided with two first guide rail convex strips (311) which are parallel to each other and a plurality of first connecting plates (312) for connecting and fixing the two first guide rail convex strips (311), a plurality of first wheels (321) are arranged at the bottom of the mold trolley (320) corresponding to the two first guide rail convex strips (311), and the mold trolley (320) moves along the first guide rail convex strips (311) through the first wheels (321);

lead screw actuating mechanism (330) includes lead screw (331), lead screw (331) with first guide rail sand grip (311) are parallel, install lead screw (331) through two bearing housing the below of mould car (320), lead screw (331) cover is equipped with the edge slide (332) that lead screw (331) removed, the top surface of slide (332) with the top surface fixed connection of mould car (320), the one end of lead screw (331) passes through coupling joint with the output shaft of second motor (333), second motor (333) are installed on first guide rail seat (310).

4. The automatic silver ingot casting device according to claim 3, wherein:

the weighing sensors (340) are fixedly arranged on the bottom surface of the first connecting plate (312), and the plurality of weighing sensors (340) form overhead support for the mold moving device (300).

5. The automatic silver ingot casting device according to claim 1, wherein:

a frame (322) for placing the forming die (350) is arranged on the top surface of the die trolley (320), and a plurality of forming dies (350) are erected on the frame (322) and distributed in a linear array along the moving direction of the die trolley (320); one end fixed mounting of frame (322) has second pneumatic cylinder (360), the piston rod one end orientation of second pneumatic cylinder (360) the central direction of frame (322), second pneumatic cylinder (360) are used for the centre gripping, fix forming die (350).

6. The automatic silver ingot casting device according to claim 1, wherein:

a second guide rail seat (610) is arranged below the lifting platform (100), the second guide rail seat (610) is provided with two second guide rail convex strips (611) which are parallel to each other and a second connecting plate (612) used for connecting and fixing the two second guide rail convex strips (611), the length direction of the two second guide rail convex strips (611) is perpendicular to the moving direction of the mold carriage (320), a plurality of second wheels (110) are installed on the bottom surface of the lifting platform (100) corresponding to the two second guide rail convex strips (611), and the lifting platform (100) moves along the second guide rail convex strips (611) through the second wheels (110); wherein two second wheels (110) which are arranged oppositely are connected through a transmission rod (120), one end of the transmission rod (120) is in transmission connection with an output shaft of a third motor (130) through a second speed reducer (140), and the third motor (130) is installed at the bottom of the lifting platform (100).

7. The automatic silver ingot casting device according to claim 1, wherein:

the first ranging sensor (510) and the second ranging sensor (520) are both laser ranging sensors.

8. The automatic silver ingot casting device according to claim 3, wherein:

a receiving groove (700) is arranged below the die trolley (320), the receiving groove (700) is positioned between the two first guide rail convex strips (311), and the receiving groove (700) is arranged along the moving track of the die trolley (320).

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