CN215358955U - Manganese steel is with unburnt not soaking low carbon low silicon slide plate brick forming device - Google Patents

Abstract

The utility model discloses a forming device of a non-burning non-soaking low-carbon low-silicon sliding plate brick for manganese steel, which comprises a bottom box, wherein a workbench is arranged on the outer wall of the top of the bottom box through bolts, an extruder body is arranged on the outer wall of the top of the workbench through bolts, an extrusion head is welded on the outer wall of one side of the extruder body, an upper die and a lower die are inserted into the outer wall of one side of the extrusion head, the upper die is arranged on the outer wall of the top of the lower die through bolts, connecting blocks are welded on the outer walls of one sides of the upper die and the lower die, fixing grooves are formed in the outer wall of the top of the connecting blocks, the connecting blocks are inserted into the extrusion head, slots are formed in the outer wall of the top of the extrusion head, and fixing plates are inserted into the slots. According to the utility model, through the arrangement of the connecting block and the fixing plate, the connecting block and the fixing plate can be convenient for workers to mount and dismount the upper die and the lower die in the using process, so that the efficiency of replacing the die by the workers can be improved.

Description

Manganese steel is with unburnt not soaking low carbon low silicon slide plate brick forming device

Technical Field

The utility model relates to the technical field of sliding plate brick processing devices, in particular to a forming device of a non-burning non-soaking low-carbon low-silicon sliding plate brick for manganese steel.

Background

At present, when a domestic large-scale ladle sliding gate is used for casting high manganese steel, an aluminum carbon sliding plate and an aluminum zirconium carbon sliding plate which are sintered at medium temperature are generally adopted, the use requirement of 2-3 times can be basically met, but a slideway is roughened to clamp steel and has larger hole expansion when in use; oil immersion and dry distillation are needed during production, the fluctuation of the qualified rate is large, the risk of hydration exists in storage and use, the production cost is high, and the use safety is influenced.

The forming device is required to form the low-carbon and low-silicon sliding plate brick in the processing process, but the existing forming device is inconvenient for workers to disassemble the die in the using process, the cooling speed is low, the cooling time is long, and the production efficiency is low, so that the problem that the forming device for the low-carbon and low-silicon sliding plate brick for the manganese steel is not burnt and is not soaked is urgently needed to be designed to solve the problem.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the defects of inconvenience in disassembly and assembly of a die and low production efficiency in the prior art, and provides a forming device of a non-burning non-soaking low-carbon low-silicon sliding plate brick for manganese steel.

In order to achieve the purpose, the utility model adopts the following technical scheme: the utility model provides a manganese steel is with not burning and not soaking low carbon low silicon slide plate brick forming device, includes the under casing, install the workstation through the bolt on the under casing top outer wall, and install the extruder body through the bolt on the workstation top outer wall, the welding has the extrusion head on the outer wall of extruder body one side, and pegs graft on the outer wall of extrusion head one side and have last mould and bed die, go up the mould and pass through the bolt and install on bed die top outer wall, and all welded the connecting block on going up mould and bed die one side outer wall, it has the fixed slot to open on the outer wall of connecting block top, the connecting block is pegged graft in the inside of extrusion head, and opens on the outer wall of extrusion head top has the slot, the inside grafting of slot has the fixed plate.

The key concept of the technical scheme is as follows: through the connecting block and the fixed plate that set up, connecting block and fixed plate can make things convenient for the staff to install and dismantle last mould and bed die at the in-process that uses, and then can improve the efficiency that the staff changed the mould.

Furthermore, mold cavities are formed in the outer walls of one sides of the upper mold and the lower mold, and water grooves are formed in the outer walls of one sides of the upper mold and the lower mold.

Furthermore, the outer walls of one sides of the upper die and the lower die are welded with water inlet pipes, and the water inlet pipes are communicated with the water tank.

Furthermore, the outer walls of one sides of the upper die and the lower die are welded with water outlet pipes which are communicated with the water tank, and the outer walls of one sides of the water inlet pipe and the water outlet pipes are provided with connecting threads.

Furthermore, the outer walls of one sides of the upper die and the lower die are provided with feed inlets, and the feed inlets are sleeved outside the output end of the extruder body.

Furthermore, a plurality of guide grooves are formed in the upper die and the lower die, and the guide grooves are located between the feed inlet and the die cavity.

Furthermore, a pulling plate is integrally formed on the outer wall of the top of the fixing plate, and an anti-skid groove is formed in the outer portion of the pulling plate.

The utility model has the beneficial effects that:

1. through the connecting block and the fixed plate that set up, connecting block and fixed plate can make things convenient for the staff to install and dismantle last mould and bed die at the in-process that uses, and then can improve the efficiency that the staff changed the mould.

2. Through the basin, inlet tube and the outlet pipe that set up, can make things convenient for the staff to cool down the inside slide plate brick of mould at the in-process that uses, improved the efficiency of cooling for fashioned speed.

3. Through the guiding groove that sets up, the guiding groove can make the distribution of raw materials in the die cavity inside more even at the in-process that uses, and then can improve the whole quality that makes the slide plate brick, has reduced the probability of the wastrel because of raw materials distributes inhomogeneous and produces.

4. Through the arm-tie and the antiskid groove that set up, the arm-tie adopts hot bad conductor to make, and then can be at the in-process speed that the in-process reduced temperature rose that uses, and then can reduce the condition that the staff was scalded and take place, and the antiskid groove can increase the frictional force between staff and the arm-tie at the in-process that uses, and then can reduce the probability that the condition of skidding takes place.

Drawings

FIG. 1 is a schematic structural diagram of a device for forming unburned, non-impregnated, low-carbon and low-silicon slide plate bricks for manganese steel, which is provided by the utility model;

FIG. 2 is a schematic structural diagram of an upper mold and a lower mold of the device for forming the unburned, non-impregnated, low-carbon and low-silicon slide plate brick for manganese steel, which is provided by the utility model;

FIG. 3 is a structural cross-sectional view of an upper mold of the device for forming the unburned, non-impregnated, low-carbon and low-silicon slide plate brick for manganese steel according to the present invention;

FIG. 4 is a side structural sectional view of an upper die and a lower die of the unfired, non-impregnated, low-carbon and low-silicon slide plate brick molding device for manganese steel.

In the figure: the extrusion device comprises a bottom box 1, a workbench 2, an extruder body 3, an extrusion head 4, an upper die 5, a lower die 6, a connecting block 7, a fixing groove 8, a slot 9, a fixing plate 10, a pulling plate 11, an anti-skidding groove 12, a water inlet pipe 13, a connecting thread 14, a water tank 15, a guide groove 16, a die groove 17, a feed inlet 18 and a water outlet pipe 19.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Please refer to fig. 1 to 4 simultaneously, a manganese steel is with not burning and not soaking low carbon low silicon slide brick forming device, including the under casing 1, install workstation 2 through the bolt on the outer wall of under casing 1 top, and install extruder body 3 through the bolt on the outer wall of workstation 2 top, the welding has extrusion head 4 on the outer wall of 3 one side of extruder body, and it has upper die 5 and bed die 6 to peg graft on the outer wall of extrusion head 4 one side, upper die 5 installs on the outer wall of 6 tops of bed die through the bolt, and all weld connecting block 7 on the outer wall of upper die 5 and one side of bed die 6, it has fixed slot 8 to open on the outer wall of connecting block 7 top, connecting block 7 pegs graft in the inside of extruding head 4, and it has slot 9 to open on the outer wall of extruding head 4 top, slot 9 is inside pegs graft and has fixed plate 10.

As apparent from the above description, the present invention has the following advantageous effects: through the connecting block 7 and the fixed plate 10 that set up, connecting block 7 and fixed plate 10 can make things convenient for the staff to install and dismantle last mould 5 and bed die 6 at the in-process that uses, and then can improve the efficiency that the staff changed the mould.

Further, mold cavities 17 are formed in the outer walls of one sides of the upper mold 5 and the lower mold 6, water channels 15 are formed in the outer walls of one sides of the upper mold 5 and the lower mold 6, and the water channels 15 are used for cooling the molds and products.

Furthermore, the outer walls of one sides of the upper die 5 and the lower die 6 are respectively welded with a water inlet pipe 13, the water inlet pipes 13 are communicated with a water tank 15, and the water inlet pipes 13 are used for water inlet.

Furthermore, water outlet pipes 19 are welded on the outer walls of one sides of the upper die 5 and the lower die 6, the water outlet pipes 19 are communicated with the water tank 15, connecting threads 14 are formed on the outer walls of one sides of the water inlet pipe 13 and the water outlet pipes 19, and the water outlet pipes 19 are used for water outlet.

Further, the outer walls of one sides of the upper die 5 and the lower die 6 are provided with feed inlets 18, the feed inlets 18 are sleeved outside the output end of the extruder body 3, and the feed inlets 18 are used for feeding.

Furthermore, a plurality of guide grooves 16 are formed in the upper die 5 and the lower die 6, and the guide grooves 16 are located between the feed inlet 18 and the die cavity 17.

Furthermore, a pulling plate 11 is integrally formed on the outer wall of the top of the fixing plate 10, the pulling plate 11 is made of a poor thermal conductor, and an anti-slip groove 12 is formed outside the pulling plate 11.

By adopting the water tank 15, the water inlet pipe 13 and the water outlet pipe 19, the temperature of the slide plate brick in the die can be conveniently reduced by workers in the using process, the temperature reduction efficiency is improved, and the forming speed is accelerated; the arranged guide groove 16, the guide groove 16 can enable the raw materials to be more uniformly distributed in the die cavity 17 in the using process, so that the overall quality of the sliding plate brick can be improved, and the probability of defective products caused by non-uniform distribution of the raw materials is reduced; the pulling plate 11 and the antiskid groove 12 that set up, the pulling plate 11 adopt hot bad conductor to make, and then can be at the in-process speed that the in-process reduced temperature rose that uses, and then can reduce the condition that the staff is scalded and take place, and the antiskid groove 12 can increase the frictional force between staff and the pulling plate 11 at the in-process that uses, and then can reduce the probability that the condition of skidding takes place.

Some preferred embodiments or application examples are listed below to help those skilled in the art to better understand the technical content of the present invention and the technical contribution of the present invention with respect to the prior art:

example 1

The utility model provides a manganese steel is with not burning and not soaking low carbon low silicon slide brick forming device, including the under casing 1, install workstation 2 through the bolt on the under casing 1 top outer wall, and install extruder body 3 through the bolt on the 2 top outer walls of workstation, the welding has extrusion head 4 on the outer wall of 3 one sides of extruder body, and it has last mould 5 and bed die 6 to peg graft on the outer wall of 4 one sides of extrusion head, it installs on 6 top outer walls of bed die through the bolt to go up mould 5, and it has connecting block 7 all to weld on the outer wall of 6 one sides of bed die 5 and bed die, it has fixed slot 8 to open on the outer wall of 7 tops of connecting block, connecting block 7 pegs graft in the inside of extrusion head 4, and it has slot 9 to open on the outer wall of 4 tops of extrusion head, the inside of slot 9 is pegged graft and is had fixed plate 10.

Wherein, the outer walls of one sides of the upper die 5 and the lower die 6 are both provided with a die cavity 17, the outer walls of one sides of the upper die 5 and the lower die 6 are both provided with a water tank 15, and the water tank 15 is used for cooling the dies and products; the outer walls of one sides of the upper die 5 and the lower die 6 are respectively welded with a water inlet pipe 13, the water inlet pipes 13 are communicated with a water tank 15, and the water inlet pipes 13 are used for water inlet; the outer walls of one sides of the upper die 5 and the lower die 6 are respectively welded with a water outlet pipe 19, the water outlet pipes 19 are communicated with the water tank 15, the outer walls of one sides of the water inlet pipe 13 and the water outlet pipes 19 are respectively provided with a connecting thread 14, and the water outlet pipes 19 are used for discharging water; the outer walls of one sides of the upper die 5 and the lower die 6 are both provided with a feed inlet 18, the feed inlet 18 is sleeved outside the output end of the extruder body 3, and the feed inlet 18 is used for feeding; a plurality of guide grooves 16 are formed in the upper die 5 and the lower die 6, and the guide grooves 16 are positioned between the feed inlet 18 and the die cavity 17; the outer wall of the top of the fixing plate 10 is integrally formed with a pulling plate 11, the pulling plate 11 is made of a poor thermal conductor, and an anti-slip groove 12 is formed in the outer portion of the pulling plate 11.

The working principle is as follows: when the extruder is used, a worker firstly pours raw materials into the extruder body 3, then installs the upper die 5 and the lower die 6 together through bolts, then inserts the connecting block 7 on the outer wall of one side of the upper die 5 and the lower die 6 onto the outer wall of one side of the extrusion head 4, then inserts the fixing plate 10 into the slot 9, then inserts the fixing plate 10 into the fixing slot 8, and at the moment, the upper die 5 and the lower die 6 are fixed; when the device is used, the raw materials are conveyed to the inner part of the feed inlet 18 by the output end of the extruder body 3 and then enter the inner part of the guide groove 16, and the guide groove 6 can ensure that the raw materials are more uniformly distributed in the die groove 17 in the using process, so that the overall quality of the slide plate brick can be improved, and the probability of defective products caused by non-uniform distribution of the raw materials is reduced; after the processing is finished, the worker takes out the fixing plate 10 and then removes the mold, and then introduces cooling water through the water inlet pipe 13, and the water flows in the water tank 15, takes away heat in the mold during the flowing process, and is discharged through the water outlet pipe 19.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (7)

1. The manganese steel non-burning non-soaking low-carbon low-silicon sliding brick forming device comprises a bottom box (1) and is characterized in that a workbench (2) is installed on the outer wall of the top of the bottom box (1) through bolts, an extruder body (3) is installed on the outer wall of the top of the workbench (2) through bolts, an extrusion head (4) is welded on the outer wall of one side of the extruder body (3), an upper die (5) and a lower die (6) are inserted and connected onto the outer wall of one side of the extrusion head (4), the upper die (5) is installed on the outer wall of the top of the lower die (6) through bolts, connecting blocks (7) are welded on the outer walls of one sides of the upper die (5) and the lower die (6), fixing grooves (8) are formed on the outer wall of the top of the connecting blocks (7), the connecting blocks (7) are inserted and connected into the extrusion head (4), and inserting grooves (9) are formed on the outer wall of the top of the extrusion head (4), the fixing plate (10) is inserted in the slot (9).

2. The forming device of the unburned, non-impregnated, low-carbon and low-silicon slide plate brick for manganese steel according to claim 1, wherein the outer walls of one sides of the upper die (5) and the lower die (6) are both provided with a die cavity (17), and the outer walls of one sides of the upper die (5) and the lower die (6) are both provided with a water tank (15).

3. The forming device of the unburned, non-impregnated, low-carbon and low-silicon slide plate brick for manganese steel according to claim 1, wherein the outer walls of one sides of the upper die (5) and the lower die (6) are welded with water inlet pipes (13), and the water inlet pipes (13) are communicated with the water tank (15).

4. The forming device of the unburned, non-impregnated, low-carbon and low-silicon slide plate brick for manganese steel according to claim 3, wherein the outer walls of one sides of the upper die (5) and the lower die (6) are welded with water outlet pipes (19), the water outlet pipes (19) are communicated with a water tank (15), and the outer walls of one sides of the water inlet pipes (13) and the water outlet pipes (19) are provided with connecting threads (14).

5. The forming device of the unburned, non-impregnated, low-carbon and low-silicon slide plate brick for manganese steel according to claim 1, wherein the outer walls of one sides of the upper die (5) and the lower die (6) are respectively provided with a feeding hole (18), and the feeding holes (18) are sleeved outside the output end of the extruder body (3).

6. The forming device of the unburned, non-impregnated, low-carbon and low-silicon slide plate brick for manganese steel according to claim 1, wherein a plurality of guide grooves (16) are formed in the upper die (5) and the lower die (6), and the guide grooves (16) are positioned between the feed inlet (18) and the die cavity (17).

7. The forming device of the unburned, non-impregnated, low-carbon and low-silicon sliding plate brick for manganese steel according to claim 1, wherein a pulling plate (11) is integrally formed on the outer wall of the top of the fixing plate (10), and the outer part of the pulling plate (11) is provided with an anti-slip groove (12).

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