CN221021526U - Magnesia carbon brick production forming device - Google Patents

Abstract

The utility model discloses a magnesia carbon brick production molding device which comprises a production molding supporting plate, wherein a disassembly assembly is arranged at the top of the production molding supporting plate and is used for replacing different magnesia carbon brick production molding dies according to requirements. According to the utility model, when the magnesia carbon brick production forming die is required to be replaced, the production forming supporting plate and the fixing bolts in the first fixing block are taken out, the first fixing block and the bottom die which are arranged are taken down from the inside of the first fixing groove, the first fixing block outside the bottom die of the replaced magnesia carbon brick production forming die is arranged in the first fixing groove, the fixing bolts are used for fixing, then the fixing bolts for fixing the second fixing block and the mounting plate are taken out, the second fixing block and the top die are taken out from the inside of the second fixing groove, and the second fixing block of the top die of the magnesia carbon brick production forming die to be replaced is arranged in the inside of the second fixing groove.

Description

Magnesia carbon brick production forming device

Technical Field

The utility model relates to the technical field of magnesia carbon brick production, in particular to a magnesia carbon brick production forming device.

Background

The magnesia carbon brick is a high-performance refractory material, is widely applied to the fields of metallurgy, chemical industry, mechanical manufacturing and the like, has the characteristics of excellent high temperature resistance, high pressure resistance, corrosion resistance, good thermal conductivity and the like, and the manufacturing process of the magnesia carbon brick mainly comprises mixing, compression molding, baking, graphitization and heat treatment, and a magnesia carbon brick production molding device is used when the magnesia carbon brick is subjected to compression molding.

Patent document CN213382092U discloses a green brick forming machine for magnesia carbon brick production, "comprising a frame, wherein the bottom of the frame is horizontally provided with a base, the middle of the frame is horizontally provided with a connecting seat, and the top of the frame is horizontally provided with a fixing seat; the plate surface of the connecting seat vertically penetrates through the connecting seat to be provided with a die frame, the upper part of the base is provided with a lower hydraulic cylinder, the telescopic end of the lower hydraulic cylinder is provided with a lower die matched with the die frame, the lower part of the fixing seat is provided with an upper hydraulic cylinder, and the telescopic end of the upper hydraulic cylinder is provided with an upper die matched with the die frame; the lower surface of the upper die is provided with an upper wear-resisting plate, the die body of the upper die is horizontally provided with a plurality of exhaust through grooves, and each exhaust through groove is provided with a plurality of exhaust through holes which are vertically downward and extend to the lower surface of the upper wear-resisting plate. The utility model is convenient for the lower die to push the green bricks to be separated, the discharging is convenient and quick, the air in the green bricks is conveniently discharged during extrusion, the green bricks have good air discharging effect, and the quality problem of green brick pressing is effectively solved. The document mainly considers the problem of how to quickly demold magnesia carbon bricks, and does not consider the problem that magnesia carbon brick production forming devices cannot produce magnesia carbon bricks with various specifications, so that the magnesia carbon brick production forming devices have singleness.

Disclosure of utility model

The utility model aims to provide a magnesia carbon brick production forming device, which aims to solve the technical problem that the magnesia carbon brick production forming device has singleness because the magnesia carbon brick production forming device cannot produce magnesia carbon bricks with various specifications.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the magnesia carbon brick production and molding device comprises a production and molding supporting plate, wherein a disassembly assembly is arranged at the top of the production and molding supporting plate and is used for replacing different magnesia carbon brick production and molding dies according to requirements;

The disassembly component comprises a production molding supporting plate, two groups of symmetrical first fixing grooves are formed in the production molding supporting plate, first fixing blocks are installed in the first fixing grooves, a production molding supporting plate, the production molding supporting plate and the first fixing blocks are installed in a penetrating mode through fixing bolts, a bottom die is installed between the two groups of first fixing blocks, a top die is installed in the bottom die, a second fixing block is installed at the top of the top die, a mounting plate is installed in the outer side of the second fixing block, a second fixing groove is formed in the mounting plate, and the second fixing blocks are installed in the second fixing grooves.

Preferably, a plurality of groups of air holes are formed in the bottom die, and the air holes are used for exhausting air during the production and molding of the magnesia carbon bricks.

Preferably, the bottom of production shaping backup pad is installed multiunit support column, and supporting baseplate is installed to the bottom of support column, and anti-skidding ground mat is installed to supporting baseplate's bottom, and anti-skidding ground mat is used for increasing the frictional force between magnesia carbon brick production shaping device and the ground, bottom hydraulic assembly is installed at supporting baseplate's top, bottom hydraulic assembly is used for promoting magnesia carbon brick and makes its drawing of patterns.

Preferably, the bottom hydraulic assembly comprises a bottom hydraulic rod, the bottom hydraulic rod is arranged at the top of the supporting bottom plate, the top of the bottom hydraulic rod is provided with a movable push plate, the movable push plate is positioned on the inner side of the production forming supporting plate, and the movable push plate is positioned above the production forming supporting plate.

Preferably, the first movable sleeve is arranged in the production molding supporting plate, the movable hole is formed in the first movable sleeve, and the bottom hydraulic rod penetrates through the movable hole.

Preferably, a plurality of groups of movable rods are arranged at the top of the production forming supporting plate, a second movable sleeve is movably arranged on the outer surface of each movable rod, a top hydraulic component is arranged on the outer side of each second movable sleeve, and the top hydraulic components are used for pressing, producing and forming magnesia carbon bricks.

Preferably, the top hydraulic assembly comprises a movable plate, the movable plate is arranged on the outer side of the second movable sleeve, the movable plate is arranged on the top of the mounting plate, the movable plate, the mounting plate and the second fixing block are arranged in a penetrating mode through fixing bolts, the top of the movable plate is provided with a top hydraulic rod, the outer side of the top hydraulic rod is provided with a fixing sleeve, the outer side of the fixing sleeve is provided with a fixing top plate, and the fixing top plate is arranged on the top of the movable rod.

Compared with the prior art, the utility model has the beneficial effects that:

1. According to the utility model, the disassembly assembly is arranged, different magnesia carbon brick production forming dies are replaced according to the requirement by using the disassembly assembly, when the magnesia carbon brick production forming dies are required to be replaced, the production forming support plate and the fixing bolts inside the first fixing block are taken out, the first fixing block and the bottom die which are arranged are taken down from the inside of the first fixing groove, the first fixing block outside the bottom die of the replaced magnesia carbon brick production forming die is arranged inside two groups of symmetrical first fixing grooves which are formed in the production forming support plate, the fixing bolts are used for fixing the first fixing block outside the bottom die of the replaced magnesia carbon brick production forming die, the production forming support plate and the production forming support plate, the installation of the bottom die of the replaced magnesia carbon brick production forming die is completed, the first fixing block and the production forming support plate are meshed with each other, the stability of the bottom die can be guaranteed by adding the fixing bolts, then the fixing bolts which are used for fixing the second fixing block and the top die matched with the bottom die of the magnesia carbon brick production forming die to be replaced are taken out from the inside the second fixing groove, the second fixing block and the top die to be used for replacing the magnesia carbon brick production forming die can be detached from the inside the second fixing plate through the second fixing device, and the installation plate can be guaranteed to be in a single magnesia carbon brick production forming device.

2. According to the utility model, the top hydraulic component is arranged, the magnesia carbon bricks are pressed and produced and molded through the top hydraulic component, the movable plate is arranged on the outer side of the movable rod through the second movable sleeve, the friction force between the movable plate and the movable rod is reduced by the second movable sleeve, the stability and the continuity of the movable plate moving up and down on the outer surface of the movable rod are ensured, the movable plate at the bottom is driven to move downwards on the outer surface of the movable rod when the top hydraulic rod stretches, so that the top mould repeatedly presses magnesia carbon brick raw materials in the bottom mould downwards for many times, after magnesia carbon bricks are produced and molded, the movable plate at the bottom is shortened and driven to move upwards on the outer surface of the movable rod by the top hydraulic component, and a space is reserved so that the movable push plate can push the produced and molded magnesia carbon bricks upwards.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic diagram of the front structure of the present utility model;

FIG. 3 is a schematic cross-sectional view of the present utility model;

FIG. 4 is a schematic view of the structure of a production molding pallet according to the present utility model;

fig. 5 is a schematic structural view of a second fixing block according to the present utility model.

In the figure: 1. producing a forming supporting plate; 2. producing a forming supporting plate; 3. a first fixing groove; 4. a first fixed block; 5. a bottom mold; 6. a top mold; 7. a second fixed block; 8. a mounting plate; 9. a second fixing groove; 10. ventilation holes; 11. a support column; 12. a support base plate; 13. an anti-slip floor mat; 14. a bottom hydraulic rod; 15. a movable push plate; 16. a first movable sleeve; 17. a movable hole; 18. a movable rod; 19. a second movable sleeve; 20. a movable plate; 21. a top hydraulic stem; 22. a fixed sleeve; 23. and fixing the top plate.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments of the present utility model. All other embodiments, which can be made by one of ordinary skill in the art without inventive faculty, are intended to be within the scope of the present utility model, based on the embodiments of the present utility model.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

Referring to fig. 1, 2, 3, 4 and 5, the present utility model provides an embodiment: the magnesia carbon brick production and molding device comprises a production and molding supporting plate 1, wherein a disassembly assembly is arranged at the top of the production and molding supporting plate 1 and is used for replacing different magnesia carbon brick production and molding dies according to requirements;

The disassembly component comprises a production molding supporting plate 2, two groups of symmetrical first fixing grooves 3 are formed in the production molding supporting plate 2, first fixing blocks 4 are arranged in the first fixing grooves 3, a production molding supporting plate 1, the production molding supporting plate 2 and the first fixing blocks 4 are installed in a penetrating mode through fixing bolts, a bottom mold 5 is installed between the two groups of first fixing blocks 4, a top mold 6 is arranged in the bottom mold 5, a second fixing block 7 is installed at the top of the top mold 6, a mounting plate 8 is installed on the outer side of the second fixing block 7, a second fixing groove 9 is formed in the mounting plate 8, and the second fixing block 7 is installed in the second fixing groove 9.

When the magnesia carbon brick production molding device is used, different magnesia carbon brick production molding dies are replaced according to the need by disassembling the assembly, when the magnesia carbon brick production molding dies are required to be replaced, the production molding supporting plate 1, the production molding supporting plate 2 and the fixing bolts inside the first fixing block 4 are taken out, the first fixing block 4 and the bottom die 5 which are installed are taken down from the inside of the first fixing groove 3, the first fixing block 4 outside the bottom die 5 of the replaced magnesia carbon brick production molding die is installed inside the two symmetrical first fixing grooves 3 which are formed in the inside of the production molding supporting plate 2, the fixing bolts are used for fixing the first fixing block 4 outside the bottom die 5 of the replaced magnesia carbon brick production molding die, the production molding supporting plate 2 and the production molding supporting plate 1, the installation of the bottom die 5 of the replaced magnesia carbon brick production molding die is completed, the first fixing block 4 and the production molding supporting plate 2 are mutually meshed, the fixing bolts are added, the stability of the bottom die 5 can be ensured, then the top die 6 matched with the bottom die 5 of the magnesia carbon brick production molding die to be replaced is firstly taken out, the second fixing block 7 and the top die 8 are installed from the inside the second fixing block 7 and the second fixing plate 8, the top die 7 is fixedly installed on the top die 7 and the top die 8 is fixedly installed on the top die 7 through the second fixing block 7 and the second fixing plate 7 and the top die 7 which is fixedly installed on the top die 6, the problem that the magnesia carbon brick production forming device has singleness because the magnesia carbon brick production forming device cannot produce magnesia carbon bricks with various specifications can be solved through the disassembly component.

A plurality of groups of ventilation holes 10 are formed in the bottom die 5, and the ventilation holes 10 are used for exhausting air during magnesia carbon brick production and molding.

The bottom of production shaping backup pad 1 is installed multiunit support column 11, production shaping backup pad 1 fixes multiunit support column 11 of bottom, guarantee multiunit support column 11's stability, supporting baseplate 12 is installed to the bottom of support column 11, supporting baseplate 12 of support column 11 to the bottom is fixed, guarantee supporting baseplate 12's stability, supporting baseplate 12's bottom is installed anti-skidding ground mat 13, supporting baseplate 12 fixes anti-skidding ground mat 13 of bottom, guarantee anti-skidding ground mat 13's stability, anti-skidding ground mat 13 is used for increasing the frictional force between magnesia carbon brick production forming device and the ground, improve this magnesia carbon brick production forming device's stability, bottom hydraulic component is installed at supporting baseplate 12's top, bottom hydraulic component is used for promoting magnesia carbon brick and makes its drawing of patterns.

The bottom hydraulic assembly comprises a bottom hydraulic rod 14, the bottom hydraulic rod 14 is arranged at the top of the supporting bottom plate 12, a movable push plate 15 is arranged at the top of the bottom hydraulic rod 14, the movable push plate 15 is positioned on the inner side of the production molding supporting plate 2, and the movable push plate 15 is positioned above the production molding supporting plate 1.

When the magnesia carbon brick production molding device is used, the magnesia carbon brick is pushed by the bottom hydraulic component to be demolded,

The height of the movable push plate 15 is consistent with the height of the production molding supporting plate 2, the bottom of the production molded magnesia carbon brick can be kept horizontal, after the magnesia carbon brick is produced and molded, the bottom hydraulic rod 14 at the top of the supporting bottom plate 12 stretches to drive the movable push plate 15 to push the production molded magnesia carbon brick upwards, so that the production molded magnesia carbon brick is convenient to be demolded, the production molded magnesia carbon brick is quickly demolded under the condition of no manual work, the operation is convenient, and the production molding efficiency of the magnesia carbon brick production molding device is improved.

The internally mounted of production shaping backup pad 1 has first movable sleeve 16, and movable hole 17 has been seted up to the inside of first movable sleeve 16, and bottom hydraulic stem 14 runs through movable hole 17, and bottom hydraulic stem 14 reciprocates in inside movable hole 17, and first movable sleeve 16 reduces the frictional force between bottom hydraulic stem 14 and the production shaping backup pad 1, guarantees the continuity that bottom hydraulic stem 14 was prolonged and shortened.

The top of production shaping backup pad 1 is installed multiunit movable rod 18, and production shaping backup pad 1 fixes the movable rod 18 at top, guarantees the stability of movable rod 18, and the surface movable mounting of movable rod 18 has second movable sleeve 19, and movable rod 18 fixes the second movable sleeve 19 of external surface, guarantees the stability of second movable sleeve 19, and top hydraulic assembly is installed in the outside of second movable sleeve 19, top hydraulic assembly is used for carrying out the suppression production shaping to the magnesia carbon brick.

The top hydraulic assembly comprises a movable plate 20, the movable plate 20 is arranged on the outer side of a second movable sleeve 19, the movable plate 20 is arranged on the top of a mounting plate 8, the movable plate 20, the mounting plate 8 and a second fixed block 7 are arranged in a penetrating mode through fixing bolts, a top hydraulic rod 21 is arranged on the top of the movable plate 20, a fixed sleeve 22 is arranged on the outer side of the top hydraulic rod 21, a fixed top plate 23 is arranged on the outer side of the fixed sleeve 22, and the fixed top plate 23 is arranged on the top of the movable rod 18.

When the magnesia carbon brick production molding device is used, magnesia carbon bricks are molded by pressing through the top hydraulic component, the movable plate 20 is installed on the outer side of the movable rod 18 through the second movable sleeve 19, the second movable sleeve 19 reduces the friction force between the movable plate 20 and the movable rod 18, stability and continuity of up-and-down movement of the movable plate 20 on the outer surface of the movable rod 18 are guaranteed, the movable plate 20 at the bottom is driven to move downwards on the outer surface of the movable rod 18 when the top hydraulic rod 21 stretches, the top mold 6 is enabled to repeatedly press magnesia carbon brick raw materials in the bottom mold 5 downwards for many times, after magnesia carbon bricks are molded, the movable plate 20 at the bottom is shortened and driven to move upwards on the outer surface of the movable rod 18, a space is reserved for the movable push plate 15 to push the magnesia carbon bricks for production molding upwards, the fixed sleeve 22 guarantees stability of the top hydraulic rod 21, friction force between the top hydraulic rod 21 and the fixed top plate 23 is increased, the fixed plate 23 of the top is fixed by the movable rod 18, and stability of the fixed plate 23 is guaranteed.

Working principle: when the magnesia carbon brick production molding device is used, magnesia carbon brick production raw materials are filled into the bottom mold 5, magnesia carbon bricks are molded by pressing through a top hydraulic component, the movable plate 20 is installed on the outer side of the movable rod 18 through a second movable sleeve 19, the friction force between the movable plate 20 and the movable rod 18 is reduced by the second movable sleeve 19, the stability and continuity of the vertical movement of the movable plate 20 on the outer surface of the movable rod 18 are ensured, the movable plate 20 at the bottom is driven to move downwards on the outer surface of the movable rod 18 when the top hydraulic rod 21 stretches, the magnesia carbon brick raw materials in the bottom mold 5 are repeatedly pressed downwards for many times by the top mold 6, and after the magnesia carbon bricks are molded, the movable plate 20 at the bottom is driven to move upwards by the top hydraulic rod 21 to leave a space so that the movable push plate 15 pushes the magnesia carbon bricks to be molded upwards;

The magnesia carbon bricks are pushed to be demolded through the bottom hydraulic component, the height of the movable push plate 15 is consistent with that of the production molding supporting plate 2, the bottom of the production molding magnesia carbon bricks can be kept horizontal, when the magnesia carbon bricks are produced and molded, the bottom hydraulic rod 14 at the top of the supporting bottom plate 12 stretches to drive the movable push plate 15 to push the production molding magnesia carbon bricks upwards, and the production molding magnesia carbon bricks are convenient to demold;

When the magnesia carbon brick production forming dies are required to be replaced, the production forming supporting plate 1, the production forming supporting plate 2 and the fixing bolts inside the first fixing blocks 4 are taken out, the first fixing blocks 4 and the bottom dies 5 which are installed are taken down from the inside of the first fixing grooves 3, the first fixing blocks 4 outside the bottom dies 5 of the replaced magnesia carbon brick production forming dies are installed inside two groups of symmetrical first fixing grooves 3 which are formed inside the production forming supporting plate 2, the fixing bolts are used for fixing the first fixing blocks 4 outside the bottom dies 5 of the replaced magnesia carbon brick production forming dies, the production forming supporting plate 2 and the production forming supporting plate 1, the installation of the bottom dies 5 of the replaced magnesia carbon brick production forming dies is completed, the first fixing blocks 4 and the production forming supporting plate 2 are meshed with each other, and the stability of the bottom dies 5 can be ensured by fixing the fixing bolts;

And then replacing the top die 6 matched with the bottom die 5 of the magnesia carbon brick production forming die to be replaced, firstly taking out the fixing bolts for fixing the second fixing block 7 and the mounting plate 8, taking out the second fixing block 7 and the top die 6 from the inside of the second fixing groove 9, installing the second fixing block 7 of the top die 6 of the magnesia carbon brick production forming die to be replaced in the inside of the second fixing groove 9, fixing the second fixing block 7 and the mounting plate 8 through the fixing bolts, and mutually engaging the second fixing block 7 and the mounting plate 8, so as to ensure the stability of the top die 6.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Claims (7)

1. The utility model provides a magnesia carbon brick production forming device, includes production shaping backup pad (1), its characterized in that: the top of the production molding supporting plate (1) is provided with a disassembly assembly, and the disassembly assembly is used for replacing different magnesia carbon brick production molding dies according to the needs;

The disassembly component comprises a production molding supporting plate (2), two groups of symmetrical first fixing grooves (3) are formed in the production molding supporting plate (2), first fixing blocks (4) are arranged in the first fixing grooves (3), a production molding supporting plate (1), the production molding supporting plate (2) and the first fixing blocks (4) are installed in a penetrating mode through fixing bolts, a bottom mold (5) is installed between the two groups of first fixing blocks (4), a top mold (6) is installed in the bottom mold (5), a second fixing block (7) is installed at the top of the top mold (6), a mounting plate (8) is installed in the outer side of the second fixing block (7), a second fixing groove (9) is formed in the mounting plate (8), and the second fixing block (7) is installed in the second fixing groove (9).

2. The magnesia carbon brick production molding device according to claim 1, wherein: a plurality of groups of ventilation holes (10) are formed in the bottom die (5), and the ventilation holes (10) are used for exhausting air during magnesia carbon brick production and molding.

3. The magnesia carbon brick production molding device according to claim 1, wherein: the bottom of production shaping backup pad (1) is installed multiunit support column (11), and supporting baseplate (12) are installed to the bottom of support column (11), and slipmat (13) are installed to the bottom of supporting baseplate (12), and slipmat (13) are used for increasing the frictional force between magnesia carbon brick production forming device and the ground, bottom hydraulic assembly is installed at the top of supporting baseplate (12), bottom hydraulic assembly is used for promoting magnesia carbon brick and makes its drawing of patterns.

4. A magnesia carbon brick production molding apparatus as claimed in claim 3, wherein: the bottom hydraulic assembly comprises a bottom hydraulic rod (14), the bottom hydraulic rod (14) is arranged at the top of the supporting bottom plate (12), the top of the bottom hydraulic rod (14) is provided with a movable push plate (15), the movable push plate (15) is positioned on the inner side of the production forming supporting plate (2), and the movable push plate (15) is positioned above the production forming supporting plate (1).

5. The magnesia carbon brick production molding device according to claim 1, wherein: the inside of the production molding supporting plate (1) is provided with a first movable sleeve (16), a movable hole (17) is formed in the first movable sleeve (16), and the bottom hydraulic rod (14) penetrates through the movable hole (17).

6. The magnesia carbon brick production molding device according to claim 1, wherein: the top of production shaping backup pad (1) is installed multiunit movable rod (18), and the surface movable mounting of movable rod (18) has second movable sleeve (19), and the top hydraulic assembly is installed in the outside of second movable sleeve (19), top hydraulic assembly is used for carrying out the suppression production shaping to the magnesia carbon brick.

7. The magnesia carbon brick production molding device according to claim 6, wherein: the top hydraulic assembly comprises a movable plate (20), the movable plate (20) is arranged on the outer side of a second movable sleeve (19), the movable plate (20) is arranged on the top of a mounting plate (8), the movable plate (20), the mounting plate (8) and a second fixed block (7) are arranged in a penetrating mode through fixing bolts, a top hydraulic rod (21) is arranged on the top of the movable plate (20), a fixed sleeve (22) is arranged on the outer side of the top hydraulic rod (21), a fixed top plate (23) is arranged on the outer side of the fixed sleeve (22), and the fixed top plate (23) is arranged on the top of the movable rod (18).