CN220825466U - Ladle pouring device of high-silicon manganese silicon electric furnace ladle - Google Patents

Abstract

The embodiment of the utility model discloses a ladle pouring device of a high silicon manganese silicon electric furnace, which comprises a ladle, a mounting block relatively fixed on the outer side wall of the ladle, a limiting assembly and a plurality of stop parts, wherein the mounting block is inserted into the limiting assembly, and when the ladle is overturned, the limiting assembly moves and is inserted into the stop parts. According to the ladle pouring device of the high-silicon manganese silicon electric furnace, when the ladle is turned over, the ladle is rapidly rotated for a small distance, at the moment, under the action of centrifugal force, the limiting component is moved and inserted into the stopping part, and the stopping part is used for stopping the limiting component, so that the rapid rotation of the mounting block and the ladle is stopped, and the ladle is turned over.

Description

Ladle pouring device of high-silicon manganese silicon electric furnace ladle

Technical Field

The utility model relates to the technical field of ladle pouring, in particular to a ladle pouring device of a high-silicon manganese silicon electric furnace ladle.

Background

The high silicon-manganese silicon alloy is a material produced by adopting a continuous method in an ore-smelting electric furnace, and after the alloy is discharged from the furnace, the alloy needs to be transported into a mold cavity through a ladle, and the molten iron flows into the mold cavity through pouring the ladle.

If the authorized bulletin number is CN213163058U, the authorized bulletin day is 2021, 05 and 11, the utility model patent of a molten iron transfer cart with an automatic ladle pouring function is named, the device comprises a cart body and a ladle, positioning columns are arranged on two sides of the ladle, the positioning columns on two sides are coaxial, a rack body is arranged on the top of the cart body, a ladle frame is hinged to the top of the rack body, a clamping groove matched with the positioning columns is formed in the middle of the ladle frame, a hydraulic cylinder is arranged between the rack body and the ladle frame, and a hydraulic system matched with the hydraulic cylinder is arranged at the bottom of the cart body. The utility model has the beneficial effects that: the utility model can realize quick and stable casting operation of molten iron, has higher safety coefficient and can reduce the probability of safety accidents.

For another example, the utility model patent with the authorized bulletin number of CN217315853U and the authorized bulletin day of 2022 and 08 month of 30 is named as a ladle pouring device, the ladle pouring device comprises a transport vehicle and a cover body assembly, wherein the top of the transport vehicle is provided with a ladle, the cover body assembly comprises a base, the top of the transport vehicle is symmetrically provided with the base, the two sides of the base are symmetrically provided with hydraulic rods, the tops of the two sides of the base are hinged with a bracket, the ladle pouring device drives the bracket to lift by starting the hydraulic rods on the two sides when molten iron is packaged with molten iron, and the bracket is hinged with the top of the base, so that a connecting plate on one side of the connecting rod is driven to fold inwards when the bracket is lifted, the semicircular body on the inner side of the connecting plate is covered on the top of the ladle, the phenomenon of molten iron sputtering caused by the subsequent casting operation of molten iron cooling concept strands and the impression of molten iron when the molten iron is transported is avoided.

In the prior art, in order to pour the ladle, it is necessary to rotate the ladle slowly, and for this purpose, it is necessary to mount the ladle on a device which drives it in rotation, however, there is still a risk of the ladle being overturned during this process.

Disclosure of utility model

The utility model aims to provide a ladle pouring device of a high-silicon manganese silicon electric furnace ladle, which aims to solve the defects in the prior art.

In order to achieve the above object, the present utility model provides the following technical solutions:

The utility model provides a ladle pouring device of high silicon manganese silicon electric stove ladle, includes ladle and relatively fixed at the installation piece of ladle lateral wall, including spacing subassembly, the installation piece is pegged graft in spacing subassembly, still includes a plurality of backstop portions, when the ladle takes place to topple, spacing subassembly motion and insert backstop portion.

The ladle pouring device of the high-silicon manganese silicon electric furnace ladle is of a cylindrical structure with the bottom sealed.

The ladle pouring device of the high-silicon manganese silicon electric furnace ladle comprises two oppositely arranged rotating columns, wherein square grooves are formed in the rotating columns, the sizes of the square grooves are larger than those of the mounting blocks, and the square grooves and the mounting blocks are correspondingly matched.

The ladle pouring device of the high-silicon manganese silicon electric furnace ladle comprises a limiting component, wherein the limiting component further comprises a through groove which is formed in the inner wall of the square groove relatively, a limiting block is slidably arranged in the through groove, an inner plate is further fixed in the through groove, a sliding rod is arranged on the inner plate in a sliding penetrating mode, a limiting spring is sleeved on the sliding rod, and the limiting spring is connected between the limiting block and the inner plate.

According to the ladle pouring device of the high-silicon manganese silicon electric furnace ladle, the through grooves are arranged along the diameter direction of the rotating column.

According to the ladle pouring device of the high-silicon manganese silicon electric furnace ladle, the limiting block extends into the square groove when at the initial position.

According to the ladle pouring device of the high-silicon manganese silicon electric furnace ladle, the upper end face of the limiting block is an inclined face.

The ladle pouring device of the high-silicon manganese silicon electric furnace ladle further comprises two supporting plates, wherein fan-shaped grooves are formed in the upper ends of the supporting plates, and the rotating columns are rotatably arranged in the corresponding fan-shaped grooves.

The ladle pouring device of the high-silicon manganese silicon electric furnace ladle is characterized in that a plurality of stop parts are fixed on the inner concave surface of the fan-shaped groove, each stop part comprises two stop blocks, the stop blocks are fixedly provided with bulges, and the bulges in the same stop parts are mutually close.

According to the ladle pouring device of the high-silicon manganese silicon electric furnace ladle, the counterweight block is fixed at one end, far away from the limiting block, of the sliding rod.

In the technical scheme, when the ladle is overturned, the ladle rapidly rotates for a small distance, and at the moment, under the action of centrifugal force, the limiting component moves and is inserted into the stop part, and the stop part stops the limiting component, so that the mounting block and the ladle are prevented from rapidly rotating to stop the ladle from overturning.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings required for the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments described in the present utility model, and other drawings may be obtained according to these drawings for a person having ordinary skill in the art.

FIG. 1 is a cross-sectional view of a ladle pouring device of a high silicon manganese silicon electric furnace provided by an embodiment of the utility model;

FIG. 2 is a cross-sectional view taken along line A-A of FIG. 1 in accordance with the present utility model;

Fig. 3 is an enlarged view of a portion at X of fig. 2 in accordance with the present utility model.

Reference numerals illustrate:

1. A ladle; 11. a mounting block; 2. a limit component; 21. rotating the column; 22. a square groove; 23. a through groove; 24. a limiting block; 25. an inner plate; 26. a sliding rod; 27. a limit spring; 28. balancing weight; 3. a stop portion; 31. a clamping block; 32. a protrusion; 4. a support plate; 41. sector grooves.

Detailed Description

In order to make the technical scheme of the present utility model better understood by those skilled in the art, the present utility model will be further described in detail with reference to the accompanying drawings.

Referring to fig. 1-3, the ladle pouring device of the high silicon manganese silicon electric furnace provided by the embodiment of the utility model comprises a ladle 1, a mounting block 11 relatively fixed on the outer side wall of the ladle 1, a limiting assembly 2, a plurality of stop parts 3, wherein the mounting block 11 is inserted into the limiting assembly 2, and when the ladle 1 is overturned, the limiting assembly 2 moves and is inserted into the stop parts 3.

In this embodiment, the ladle 1 is a tool for transferring molten iron in the prior art, and will not be described in detail herein, the mounting block 11 is of a square structure, and the limiting assembly 2 is configured to limit and mount the mounting block 11, that is, limit the ladle 1; in order to slowly rotate the ladle 1, the ladle can be driven to slowly rotate by a driving member, which is preferably a hydraulic cylinder, except for manual work, and the description is not repeated here; if the ladle 1 is driven to rotate slowly by manpower, the ladle 1 may be overturned due to improper operation of a worker, if the ladle 1 is driven to rotate slowly by the driving member, after multiple uses, the joint of the driving member and the ladle 1 may break or fall off to cause the ladle 1 to overtake; when the ladle 1 is tipped, the ladle 1 is rapidly rotated a small distance, and at this time, the stopper assembly 2 is moved into the stopper 3 by the centrifugal force, and the stopper assembly 2 is blocked by the stopper 3, thereby blocking the mounting block 11 and the ladle 1 from rapidly rotating to stop the ladle 1 from being tipped.

In yet another embodiment, the ladle 1 is a bottom-sealed cylindrical structure for carrying and transferring molten iron.

In still another embodiment of the present utility model, the limiting component 2 includes two oppositely disposed rotating columns 21, a square groove 22 is formed on the rotating columns 21, the size of the square groove 22 is larger than that of the mounting block 11, and the square groove 22 and the mounting block 11 are correspondingly matched; the limiting assembly 2 further comprises a through groove 23 which is formed in the inner wall of the square groove 22 relatively, the through groove 23 penetrates through the rotating column 21, a limiting block 24 is slidably mounted in the through groove 23, and the distance between the limiting block 24 and the bottom wall of the square groove 22 is equal to the thickness of the mounting block 11, so that the movement of the mounting block 11 can be stabilized, an inner plate 25 is further fixed in the through groove 23, a sliding rod 26 is slidably arranged on the inner plate 25 in a penetrating manner, a limiting spring 27 is sleeved on the sliding rod 26, and the limiting spring 27 is connected between the limiting block 24 and the inner plate 25; when the ladle 1 is required to be mounted on the rotary column 21, the ladle 1 is lifted to align the mounting block 11 with the square groove 22, the ladle 1 is moved downwards to enable the mounting block 11 to be inserted into the square groove 22, the mounting block 11 continues to move to press the limiting block 24 to move into the through groove 23, at the moment, the limiting spring 27 is synchronously compressed, and when the mounting block 11 completely moves to the lower part of the limiting block 24, the limiting block 24 pops up under the elastic action of the limiting spring 27, and the mounting block 11 is limited through the limiting block 24, so that the ladle 1 is limited.

In still another embodiment of the present utility model, the through groove 23 is disposed along the diameter direction of the rotating post 21, so that when the limiting block 24 slides, the sliding rod 26 can be driven to slide along the diameter direction of the rotating post 21, so as to facilitate the limiting component 2 to be inserted into the stop portion 3.

In yet another embodiment of the present utility model, the stopper 24 extends into the square groove 22 at the initial position, so that the stopper 24 can be pressed to move when the mounting block 11 is inserted into the square groove 22.

In still another embodiment of the present utility model, the upper end surface of the limiting block 24 is an inclined surface, so that the mounting block 11 can press the limiting block 24 to move into the through groove 23.

In still another embodiment provided by the utility model, the ladle furnace further comprises two support plates 4, wherein the upper ends of the support plates 4 are provided with sector grooves 41, the rotating columns 21 are rotatably arranged in the corresponding sector grooves 41, and the ladle 1 and the mounting blocks 11 are limited and supported by the support plates 4; a movable bottom plate is connected between the support plates 4, so that the ladle 1 can be conveniently moved.

In still another embodiment of the present utility model, a plurality of the stopping portions 3 are fixed on the concave surface of the fan-shaped groove 41, each stopping portion 3 includes two locking blocks 31, the protrusions 32 are fixed on the locking blocks 31, the protrusions 32 in the same stopping portion 3 are close to each other, when the ladle 1 is tipped over, the ladle 1 is rapidly rotated for a small distance, at this time, the sliding rod 26 slides outwards under the action of centrifugal force and is inserted into the locking blocks 31, and the sliding rod 26 is prevented from rotating by the locking blocks 31, so that the ladle 1 is prevented from rotating.

Obviously, in the normal state, the sliding rod 26 pushes the limiting block 24 to extend out to limit the mounting block 11, when the ladle 1 is overturned, the sliding rod 26 moves in the opposite direction, so that the stop part 3 is inserted, thus, two functions can be realized through the sliding rod 26, one of which is used for limiting the ladle 1, and the other is used for preventing the ladle 1 from rotating rapidly and preventing the ladle from overturning.

In still another embodiment of the present utility model, a weight block 28 is fixed at one end of the sliding rod 26 away from the limiting block 24, the weight block 28 and the stop portion 3 are correspondingly matched, and the weight block 28 is used for weighting one end of the sliding rod 26 away from the limiting block 24, so that the sliding rod 26 can smoothly slide out of the through groove 23, and is convenient for being clamped into the stop portion 3.

While certain exemplary embodiments of the present utility model have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that modifications may be made to the described embodiments in various different ways without departing from the spirit and scope of the utility model. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive of the scope of the utility model, which is defined by the appended claims.

Claims (10)

1. The utility model provides a ladle pouring device of high silicon manganese silicon electric stove ladle, includes ladle and relatively fixed at the installation piece of ladle lateral wall, its characterized in that, including spacing subassembly, the installation piece is pegged graft in spacing subassembly, still includes a plurality of backstop portions, when the ladle takes place to topple, spacing subassembly motion inserts backstop portion.

2. The ladle pouring device of the high silicon manganese silicon electric furnace ladle according to claim 1, wherein the ladle is of a cylindrical structure with a sealed bottom.

3. The ladle pouring device of the high-silicon manganese silicon electric furnace ladle according to claim 1, wherein the limiting assembly comprises two oppositely arranged rotating columns, square grooves are formed in the rotating columns, the sizes of the square grooves are larger than those of the mounting blocks, and the square grooves and the mounting blocks are correspondingly matched.

4. The ladle pouring device of the high-silicon manganese silicon electric furnace ladle according to claim 3, wherein the limiting assembly further comprises a through groove which is relatively arranged on the inner wall of the square groove, the limiting block is slidably arranged in the through groove, an inner plate is further fixed in the through groove, a sliding rod is slidably arranged on the inner plate in a penetrating manner, a limiting spring is sleeved on the sliding rod, and the limiting spring is connected between the limiting block and the inner plate.

5. The ladle pouring device for the high silicon manganese silicon electric furnace according to claim 4, wherein the through grooves are arranged along the diameter direction of the rotating column.

6. The ladle pouring device of the high silicon manganese silicon electric furnace ladle as recited in claim 4 wherein the limiting block extends into the square groove when in an initial position.

7. The ladle pouring device of the high-silicon manganese silicon electric furnace ladle as recited in claim 4, wherein the upper end surface of the limiting block is an inclined surface.

8. The ladle pouring device of the high-silicon manganese silicon electric furnace ladle according to claim 3, further comprising two supporting plates, wherein fan-shaped grooves are formed in the upper ends of the supporting plates, and the rotating columns are rotatably installed in the corresponding fan-shaped grooves.

9. The ladle pouring device of the high-silicon manganese silicon electric furnace ladle according to claim 8, wherein a plurality of stopping parts are fixed on the inner concave surface of the fan-shaped groove, each stopping part comprises two clamping blocks, the clamping blocks are fixedly provided with bulges, and the bulges in the same stopping part are mutually close.

10. The ladle pouring device of the high-silicon manganese silicon electric furnace ladle as recited in claim 4, wherein a balancing weight is fixed at one end of the sliding rod away from the limiting block.