CN111922274A - Steel forging equipment for steelmaking - Google Patents

Abstract

The invention relates to steel forging equipment, in particular to steel forging equipment for steelmaking, which comprises a fixing mechanism, an automatic rotating mechanism, a forging mechanism and an automatic discharging mechanism, wherein the equipment can clamp steel to be forged, can rotate the steel, can forge the steel by a pressing block, can automatically output the forged steel, is connected with the automatic rotating mechanism, is connected with the forging mechanism, is connected with the fixing mechanism, is connected with the automatic discharging mechanism, and is connected with the automatic discharging mechanism.

Description

Steel forging equipment for steelmaking

Technical Field

The invention relates to steel forging equipment, in particular to steel forging equipment for steelmaking.

Background

In the steel forging, the processes are more, most processes need different manual operation equipment for processing, the generated labor cost is higher, but no better steel forging equipment exists in the market, so the steel forging equipment for steelmaking is designed.

Disclosure of Invention

The invention mainly solves the technical problem of providing steel forging equipment for steelmaking, wherein the equipment can clamp steel to be forged, the equipment can rotate the steel, the equipment can forge the steel by using a pressing block, and the equipment can automatically output the forged steel.

In order to solve the technical problems, the invention relates to steel forging equipment, in particular to steel forging equipment for steelmaking, which comprises a fixing mechanism, an automatic rotating mechanism, a forging mechanism and an automatic discharging mechanism, wherein the equipment can clamp steel to be forged, can rotate the steel, can forge the steel by using a pressing block, and can automatically output the forged steel.

The automatic discharging mechanism is connected with the automatic discharging mechanism, and the automatic rotating mechanism is connected with the automatic discharging mechanism.

As a further optimization of the technical scheme, the steel forging equipment for steelmaking provided by the invention comprises a handle, a compression shaft, a spring connecting block, a pressure spring, an equipment installation side plate, a spring connecting plate, an installation plate and an equipment installation bottom plate, wherein the handle is connected with the compression shaft, the compression shaft is connected with the spring connecting block, one side of the pressure spring is connected with the spring connecting block, the other side of the pressure spring is connected with the spring connecting plate, the equipment installation side plate is connected with the compression shaft in a sliding manner, the spring connecting plate is connected with the compression shaft in a sliding manner, the installation plate is connected with the compression shaft in a sliding manner, the equipment installation bottom plate is connected with the equipment installation side plate, the spring connecting plate is connected with the.

As a further optimization of the technical scheme, the steel forging equipment for steelmaking of the invention comprises a linkage motor, a motor shaft, a special-shaped gear a, a gear shaft, a rack limiting plate, a hinged plate pulley, a pulley shaft, a rotating rod, a rotating shaft, a hinged pressing plate, a belt a, a transmission shaft, a belt b, a friction shaft, a bearing plate, a belt c, a connecting shaft, a gear, a special-shaped gear b, an equipment mounting plate and a friction transmission belt, wherein the linkage motor is connected with the motor shaft, the motor shaft is connected with the special-shaped gear a, the gear is connected with the gear shaft, the gear shaft is connected with the equipment mounting plate bearing, the rack is meshed with the gear, the rack limiting plate is connected with the rack in a sliding manner, the two hinged plates are hinged with the rack, the rotating rod is connected with the hinged plate in a sliding way, the rotating shaft is connected with a rotating rod bearing, the hinged compression plate is hinged with the rotating rod, the compression plate is hinged with the hinged compression plate, the belt a is connected with a motor shaft in a friction way, one transmission shaft is connected with the belt a in a friction way, the belt b is connected with two transmission shafts in a friction way, the friction shaft is connected with a bearing plate bearing, the bearing plate is connected with an equipment mounting plate, the belt c is connected with a friction shaft, the connecting shaft is connected with the belt c in a friction way, a gear is connected with a connecting shaft in a friction way, a special-shaped gear b is connected with the compression shaft, the equipment mounting plate is connected with a linkage motor, the friction transmission belt is connected with the transmission shaft in a friction way, the pulley shaft is connected with the equipment mounting plate, the connecting shaft is connected with the equipment installation side plate bearing.

As a further optimization of the technical scheme, the steel forging equipment for steelmaking comprises a linkage hinged plate a, a linkage hinged plate b, a connecting plate a, a linkage shaft, a linkage block, a stirring shaft, a linkage spring, an internal thread rotating wheel, a limiting shaft, a limiting block, a limiting spring, a reset connecting plate a, a reset connecting plate b, a reset shaft, a reset spring, a slide rail, a slide connecting plate, a linkage transmission shaft a, a linkage transmission shaft b, a linkage power gear, an external thread shaft and a pressing block, wherein the linkage hinged plate a is hinged with the linkage hinged plate b, the linkage hinged plate b is connected with the connecting plate a, the connecting plate a is connected with the linkage shaft in a sliding manner, the linkage shaft is connected with the linkage block, the stirring shaft is connected with the stirring shaft in a sliding manner through a groove in the internal thread rotating wheel, the linkage spring is sleeved on the linkage shaft and limited on the connecting, the upper sides of the two internal thread rotating wheels are meshed with a linkage power gear, a limiting shaft is connected with the limiting block, the limiting block is connected with the two internal thread rotating wheels in a sliding manner, a limiting spring is sleeved on the limiting shaft and is limited on the limiting block and a sliding connecting plate, a resetting connecting plate a is connected with a resetting shaft, a resetting connecting plate b is connected with the resetting shaft in a sliding manner, a resetting spring is sleeved on the resetting shaft and is limited on the resetting connecting plate a and the resetting connecting plate b, a sliding rail is connected with the sliding connecting plate in a sliding manner, the sliding connecting plate is connected with the limiting shaft in a sliding manner, a linkage transmission shaft a is connected with a belt b in a friction manner, a linkage transmission shaft b is connected with a belt b in a friction manner, a linkage power gear is connected with a linkage transmission shaft b, an external thread shaft is connected, connecting plate an and equipment mounting panel sliding connection, two internal thread swiveling wheels and equipment mounting panel sliding connection, reset connecting plate an and equipment mounting panel sliding connection, reset connecting plate b and equipment mounting panel are connected, and the slide rail is connected with the equipment mounting panel, and sliding connection board and equipment mounting panel sliding connection, linkage transmission shaft an and equipment mounting panel bearing connection, linkage transmission shaft b and equipment mounting panel bearing connection, external screw thread axle and equipment mounting panel sliding connection.

As a further optimization of the technical scheme, the steel forging equipment for steelmaking comprises an automatic discharging mechanism, a discharging motor shaft, a discharging belt, a discharging gear, a discharging rack, a rack connecting plate, a discharging reset spring, a discharging reset shaft, a discharging limiting plate, a mounting plate a, a discharging pressing block, a pressing block sliding plate, an inclined plate and an inclined connecting plate, wherein the discharging motor is connected with the discharging motor shaft, the two discharging motor shafts are in friction connection with the discharging belt, the discharging gear is connected with the discharging motor shaft, the discharging rack is meshed with the discharging gear, the rack connecting plate is connected with the two discharging racks, the discharging reset spring is sleeved on the discharging reset shaft and limited on the rack connecting plate and the mounting plate a, the discharging limiting plate is connected with the two discharging racks, the mounting plate a is in sliding connection with the discharging rack, and the discharging pressing block is connected, oppression piece sliding plate is connected with two mounting panels, the hang plate is connected with oppression piece sliding plate, the slope connecting plate is connected with the hang plate, ejection of compact motor is connected with the equipment fixing bottom plate, an ejection of compact motor shaft is connected with equipment fixing bottom plate bearing, ejection of compact reset shaft and mounting panel a sliding connection, mounting panel a is connected with two equipment fixing curb plates, mounting panel a is connected with the equipment fixing bottom plate, mounting panel a is connected with the equipment fixing board, ejection of compact oppression piece and oppression piece sliding plate sliding connection, the slope connecting plate is connected with the equipment fixing bottom plate.

As a further optimization of the technical scheme, the steel forging equipment for steelmaking is characterized in that the pressing block is made of alloy steel with high density.

The steel forging equipment for steelmaking provided by the invention has the beneficial effects that:

the steel forging equipment for steelmaking can clamp steel to be forged, can rotate the steel, can forge the steel by the pressing block, and can automatically output the forged steel.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic structural view of a steel forging apparatus for steelmaking according to the present invention.

FIG. 2 is a first schematic structural view of a fixing mechanism 1 of a steel forging apparatus for steelmaking according to the present invention.

FIG. 3 is a second schematic structural view of a fixing mechanism 1 of a steel forging apparatus for steel making according to the present invention.

FIG. 4 is a third schematic structural view of a fixing mechanism 1 of a steel forging apparatus for steel making according to the present invention.

FIG. 5 is a first schematic structural view of an automatic rotating mechanism 2 of the steel forging apparatus for steel making according to the present invention.

FIG. 6 is a second schematic structural view of an automatic rotating mechanism 2 of the steel forging apparatus for steel making according to the present invention.

FIG. 7 is a third schematic structural view of an automatic rotating mechanism 2 of the steel forging apparatus for steel making according to the present invention.

FIG. 8 is a first schematic structural view of a forging mechanism 3 of the steel forging apparatus for steel making according to the present invention.

FIG. 9 is a second schematic structural view of a forging mechanism 3 of the steel forging apparatus for steel making according to the present invention.

FIG. 10 is a third schematic structural view of a forging mechanism 3 of the steel forging apparatus for steel making according to the present invention.

FIG. 11 is a fourth schematic structural view of a forging mechanism 3 of the steel forging apparatus for steel making according to the present invention.

FIG. 12 is a fifth schematic structural view of a forging mechanism 3 of the steel forging apparatus for steel making according to the present invention.

FIG. 13 is a sixth schematic structural view of a forging mechanism 3 of the steel forging apparatus for steel making according to the present invention.

FIG. 14 is a seventh schematic structural view of a forging mechanism 3 of the steel forging apparatus for steel making according to the present invention.

FIG. 15 is a first schematic structural view of an automatic discharging mechanism 4 of a steel forging apparatus for steel making according to the present invention.

FIG. 16 is a second schematic structural view of an automatic discharging mechanism 4 of a steel forging apparatus for steel making according to the present invention.

FIG. 17 is a third schematic structural view of an automatic discharging mechanism 4 of a steel forging apparatus for steel making according to the present invention.

FIG. 18 is a schematic structural view of a mounting plate a4-10 of the steel forging apparatus for steel production according to the present invention.

In the figure: a fixing mechanism 1; 1-1 of a handle; pressing the shaft 1-2; 1-3 parts of a spring connecting block; 1-4 of a pressure spring; equipment installation side plates 1-5; spring connecting plates 1-6; mounting plates 1-7; 1-8 of an equipment installation bottom plate; an automatic rotating mechanism 2; a linkage motor 2-1; a motor shaft 2-2; a special-shaped gear a 2-3; 2-4 parts of gear; 2-5 parts of a gear shaft; 2-6 of racks; 2-7 rack limiting plates; hinge plates 2-8; hinge plate pulleys 2-9; 2-10 parts of pulley shaft; rotating rods 2-11; 2-12 of a rotating shaft; hinged compression plates 2-13; 2-14 of a compression plate; belts a 2-15; 2-16 parts of a transmission shaft; belts b 2-17; 2-18 of a friction shaft; bearing plates 2-19; belts c 2-20; connecting shafts 2-21; gears 2-22; a special-shaped gear b 2-23; equipment mounting plates 2-24; 2-25 parts of a friction transmission belt; a forging mechanism 3; the linkage hinge plate a 3-1; the linkage hinge plate b 3-2; connection board a 3-3; 3-4 of a linkage shaft; 3-5 of a linkage block; 3-6 of a shifting shaft; 3-7 of a linkage spring; 3-8 parts of an internal thread rotating wheel; 3-9 parts of a limiting shaft; 3-10 parts of a limiting block; 3-11 parts of a limiting spring; reset connecting plate a 3-12; reset connecting plate b 3-13; reset shafts 3-14; 3-15 parts of a return spring; 3-16 parts of a slide rail; sliding connection plates 3-17; linkage drive shaft a 3-18; linkage transmission shafts b 3-19; 3-20 parts of linkage power gear; 3-21 parts of external thread shaft; 3-22 parts of a compression block; an automatic discharging mechanism 4; a discharge motor 4-1; a discharging motor shaft 4-2; 4-3 of a discharging belt; 4-4 parts of a discharging gear; 4-5 of a discharge rack; 4-6 of a rack connecting plate; 4-7 parts of a discharging reset spring; 4-8 parts of a discharging reset shaft; 4-9 parts of a discharging limiting plate; mounting plate a 4-10; 4-11 parts of a discharge pressing block; a pressing block sliding plate 4-12; inclined plates 4-13; the webs 4-14 are inclined.

Detailed Description

The first embodiment is as follows:

the present embodiment will be described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and fig. 18, and the present invention relates to a steel material forging apparatus, and more specifically, to a steel material forging apparatus for steel making, which includes a fixing mechanism 1, an automatic rotating mechanism 2, a forging mechanism 3, and an automatic discharging mechanism 4, and which can clamp a steel material to be forged, can rotate the steel material, can forge the steel material with a pressing block, and can automatically output the forged steel material.

Fixing mechanism 1 is connected with automatic rotary mechanism 2, and automatic rotary mechanism 2 is connected with forging mechanism 3, and forging mechanism 3 is connected with fixing mechanism 1, and automatic discharging mechanism 4 is connected with fixing mechanism 1, and fixing mechanism 1 is connected with automatic discharging mechanism 4, and automatic rotary mechanism 2 is connected with automatic discharging mechanism 4.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and fig. 18, and the embodiment further describes the embodiment, where the fixing mechanism 1 includes a handle 1-1, a pressing shaft 1-2, a spring connecting block 1-3, a pressure spring 1-4, an equipment-mounting side plate 1-5, a spring connecting plate 1-6, a mounting plate 1-7, an equipment-mounting bottom plate 1-8, the handle 1-1 is connected with the pressing shaft 1-2, the pressing shaft 1-2 is connected with the spring connecting block 1-3, one side of the pressure spring 1-4 is connected with the spring connecting block 1-3, and the other side is connected with the spring connecting plate 1-6, the equipment installation side plate 1-5 is connected with the pressing shaft 1-2 in a sliding mode, the spring connecting plate 1-6 is connected with the pressing shaft 1-2 in a sliding mode, the mounting plate 1-7 is connected with the pressing shaft 1-2 in a sliding mode, the equipment installation bottom plate 1-8 is connected with the equipment installation side plate 1-5, the spring connecting plate 1-6 is connected with the equipment installation bottom plate 1-8, the mounting plate 1-7 is connected with the equipment installation bottom plate 1-8, the equipment can clamp steel to be forged, two handles 1-1 are pulled, the handles 1-1 drive the pressing shaft 1-2 to move outside the equipment, the pressing shaft 1-2 drives the spring connecting block 1-3 to move outside the equipment, the installation side plate 1-5 and the spring connecting plate 1-6 limit the relative position of the pressing shaft 1-2, the spring connecting blocks 1-3 press the pressure springs 1-4, so that the pressure springs 1-4 press the spring connecting plates 1-6, when the two pressing shafts 1-2 are pulled to form a gap, steel to be forged is placed between the two pressing shafts 1-2, the pulling of the handle 1-1 is stopped, and the two pressing shafts 1-2 extrude the steel under the action of the pressure springs 1-4, so that the steel is clamped.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, and fig. 18, and the embodiment further describes the embodiment, where the automatic rotating mechanism 2 includes a linkage motor 2-1, a motor shaft 2-2, a profile gear a2-3, a gear 2-4, a gear shaft 2-5, a rack 2-6, a rack stopper plate 2-7, a hinge plate 2-8, a hinge plate pulley 2-9, a pulley shaft 2-10, a rotating rod 2-11, a rotating shaft 2-12, a hinge pressing plate 2-13, pressing plate 2-14, a belt a2-15, a driving shaft 2-16, a belt b2-17, a friction shaft 2-18, Bearing plates 2-19, belts c2-20, connecting shafts 2-21, gears 2-22, special-shaped gears b2-23, equipment mounting plates 2-24 and friction transmission belts 2-25, a linkage motor 2-1 is connected with a motor shaft 2-2, the motor shaft 2-2 is connected with the special-shaped gears a2-3, gears 2-4 are connected with gear shafts 2-5, the gear shafts 2-5 are connected with the equipment mounting plates 2-24 through bearings, racks 2-6 are meshed with the gears 2-4, rack limiting plates 2-7 are connected with the racks 2-6 in a sliding manner, two hinge plates 2-8 are hinged with the racks 2-6, pulleys 2-9 are connected with the hinge plates 2-8 in a friction manner, pulley shafts 2-10 are connected with the hinge plate pulleys 2-9 through bearings, the rotating rod 2-11 is connected with the hinged plate 2-8 in a sliding way, the rotating shaft 2-12 is connected with the rotating rod 2-11 by a bearing, the hinged compression plate 2-13 is hinged with the rotating rod 2-11, the compression plate 2-14 is hinged with the hinged compression plate 2-13, the belt a2-15 is connected with the motor shaft 2-2 in a friction way, one transmission shaft 2-16 is connected with the belt a2-15 in a friction way, the belt b2-17 is connected with the two transmission shafts 2-16 in a friction way, the friction shaft 2-18 is connected with the bearing plate 2-19 by a bearing, the bearing plate 2-19 is connected with the equipment mounting plate 2-24, the belt c2-20 is connected with the friction shaft 2-18 in a friction way, the connecting shaft 2-21 is connected with the belt c2-20 in a friction way, and, the special-shaped gear b2-23 is connected with a pressing shaft 1-2, the equipment mounting plate 2-24 is connected with a linkage motor 2-1, a friction transmission belt 2-25 is in friction connection with a transmission shaft 2-16, a pulley shaft 2-10 is connected with the equipment mounting plate 2-24, a rotating shaft 2-12 is connected with an equipment mounting side plate 1-5, the pressing plate 2-14 is in sliding connection with the equipment mounting plate 2-24, the transmission shaft 2-16 is in bearing connection with the equipment mounting plate 2-24, a friction shaft 2-18 is in friction connection with the friction transmission belt 2-25, and a connecting shaft 2-21 is in bearing connection with the equipment mounting side plate 1-5.

The fourth concrete implementation mode:

the forging mechanism 3 comprises a linkage hinged plate a3-1, a linkage hinged plate b3-2, a connecting plate a3-3, a linkage shaft 3-4, a linkage block 3-5, a stirring shaft 3-6, a linkage spring 3-7, an internally threaded rotating wheel 3-8, a limiting shaft 3-9, a limiting block 3-10, a limiting spring 3-11, a reset connecting plate a3-12, a reset connecting plate b3-13, a reset shaft 3-14, a reset spring 3-15, a sliding rail 3-16, a sliding connecting plate 3-17, a sliding block 3-9, a limiting block 3-11, a reset connecting plate a3-12, a reset connecting plate b3-13, a reset shaft 3-14, a reset spring 3-15, a sliding rail 3-16, a sliding connecting plate 3-17 and a reset spring, A linkage transmission shaft a3-18, a linkage transmission shaft b3-19, a linkage power gear 3-20, an external thread shaft 3-21 and a pressing block 3-22, a linkage hinged plate a3-1 is hinged with a linkage hinged plate b3-2, a linkage hinged plate b3-2 is connected with a connecting plate a3-3, a connecting plate a3-3 is connected with a linkage shaft 3-4 in a sliding way, a linkage shaft 3-4 is connected with a linkage block 3-5, a linkage block 3-5 is connected with a shifting shaft 3-6, a shifting shaft 3-6 is connected with a groove on an internally threaded rotating wheel 3-8 in a sliding way, a linkage spring 3-7 is sleeved on the linkage shaft 3-4 and limited on the connecting plate a3-3 and the linkage block 3-5, the upper sides of the two internally threaded rotating wheels 3-8 are meshed with the linkage power gear 3-20, the limiting shaft 3-9 is connected with the limiting block 3-10, the limiting block 3-10 is connected with two internal thread rotating wheels 3-8 in a sliding way, the limiting spring 3-11 is sleeved on the limiting shaft 3-9 and limited on the limiting block 3-10 and a sliding connecting plate 3-17, a resetting connecting plate a3-12 is connected with a resetting shaft 3-14, a resetting connecting plate b3-13 is connected with a resetting shaft 3-14 in a sliding way, the resetting spring 3-15 is sleeved on the resetting shaft 3-14 and limited on a resetting connecting plate a3-12 and a resetting connecting plate b3-13, a sliding rail 3-16 is connected with the sliding connecting plate 3-17 in a sliding way, the sliding connecting plate 3-17 is connected with the limiting shaft 3-9 in a sliding way, a linkage transmission shaft a3-18 is connected with a belt 387b 2-17 in a friction way, and a linkage transmission shaft b3-, the linkage power gears 3-20 are connected with the linkage transmission shafts b3-19, the externally threaded shafts 3-21 are in threaded connection with the internally threaded rotating wheels 3-8, the pressing blocks 3-22 are in bearing connection with the externally threaded shafts 3-21, the linkage hinge plate a3-1 is in sliding connection with the equipment mounting plate 2-24, the linkage hinge plate b3-2 is in sliding connection with the equipment mounting plate 2-24, the connecting plate a3-3 is in sliding connection with the equipment mounting plate 2-24, the two internally threaded rotating wheels 3-8 are in sliding connection with the equipment mounting plate 2-24, the reset connecting plate a3-12 is in sliding connection with the equipment mounting plate 2-24, the reset connecting plate b3-13 is connected with the equipment mounting plate 2-24, the slide rails 3-16 are connected with the equipment mounting plate 2-24, and the slide connecting plates 3-17 are, the linkage transmission shaft a3-18 is in bearing connection with the equipment mounting plate 2-24, the linkage transmission shaft b3-19 is in bearing connection with the equipment mounting plate 2-24, the external thread shaft 3-21 is in sliding connection with the equipment mounting plate 2-24, the equipment can rotate steel, the equipment can forge steel by using a pressing block, the linkage motor 2-1 works to drive the special-shaped gear a2-3 to rotate through the linkage motor 2-1, the special-shaped gear a2-3 rotates to drive the gear 2-4 to intermittently rotate by taking the gear shaft 2-5 as an axis, the gear 2-4 moves to drive the rack 2-6 to transversely move under the limitation of the two rack limiting plates 2-7, when the rack 2-6 moves towards the direction of the belt b2-17, the hinge plate 2-8 is driven to take a hinge plate pulley 2-9 as a fulcrum, the rotating rod 2-11 is pressed to move in a direction far away from the belt b2-17, a certain gap amount is reserved between the two hinge plate pulleys 2-9 and the hinge plates 2-8, so that the movement obstacle of the hinge plate pulleys 2-9 to the hinge plates 2-8 when the hinge plates 2-8 rotate is avoided, the rotating rod 2-11 is pressed to rotate by taking the rotating shaft 2-12 as a shaft, the other side of the rotating rod 2-11 is pressed to drive the hinge compression plates 2-13 to compress the compression plates 2-14, the compression plates 2-14 are pressed to drive the compression shaft 1-2 to move, when the compression shaft 1-2 moves upwards to a limit position, the special-shaped gear a2-3 is not engaged with the rack 2-6, and the motor shaft 2-2 rotates, the belt a2-15 drives the transmission shaft 2-16 to rotate, the transmission shafts 2-16 rotate to drive the other transmission shaft 2-16 on the same side to rotate through the friction transmission belts 2-25, the transmission shafts 2-16 drive the transmission shafts 2-16 on the other side to rotate through the belts b2-17, at the moment, the four transmission shafts 2-16 rotate simultaneously, the friction transmission belts 2-25 drive the friction shafts 2-18 to rotate when moving along, the friction shafts 2-18 rotate to drive the connecting shafts 2-21 to rotate through the belts c2-20, the connecting shafts 2-21 rotate to drive the gears 2-22 to rotate, the gears 2-22 rotate to drive the special-shaped gears b2-23 on the pressing shafts 1-2 to rotate, the gears 2-22 are quarter gears, so the special-shaped gears b2-23 stop rotating after rotating for 90 degrees, and at the moment, the pressing shafts 1-2 are at the upward movement limit position, because the pressing shaft 1-2 and the two pressing shafts 1-2 clamp steel materials under the influence of gravity, the pressing shaft 1-2 starts to move downwards, the gear 2-22 and the special-shaped gear b2-23 are not meshed, the equipment is reset, the rack 2-6 returns to the initial position, the linked hinge plate a3-1 is also driven to move when the rack 2-6 moves, when the rack 2-6 moves towards the belt b2-17 direction, the two linked hinge plates a3-1 move to drive the linked hinge plate b3-2 to move towards the direction far away from the center of the equipment under the limitation of the two slide rails 3-16, the two linked hinge plates b3-2 move to drive the two connecting plates a3-3, the connecting plates a3-3 move to pull the linked blocks 3-5 through the linked springs 3-7, the two linked blocks 3-5 pull the two internally threaded rotating wheels 3-8 to separate through the shifting shafts 3-6, under the action of the groove on the upper side of the internal thread rotating wheel 3-8, the stirring shafts 3-6 pull the internal thread rotating wheel 3-8 to move towards two sides when separating, the connecting plate a3-3 also drives the sliding connecting plate 3-17 to move when moving, the sliding connecting plate 3-17 drives the limiting shaft 3-9, the limiting block 3-10 and the limiting spring 3-11 to move when moving, under the action of the limiting shaft 3-9, the limiting block 3-10 and the limiting spring 3-11, the two stirring shafts 3-6 can pull the two internal thread rotating wheels 3-8 to move when separating the internal thread rotating wheel 3-8, the internal thread rotating wheel 3-8 does transverse reciprocating motion in following the motion of the linkage hinge plate a3-1, namely the internal thread rotating wheel 3-8 is opened to reciprocate after contacting, the friction transmission belts 2-25 also drive the linkage transmission shafts a3-18 to move when moving, so that the linkage transmission shafts a3-18 rotate, the linkage transmission shafts a3-18 rotate to help the friction connection relationship between the friction transmission belts 2-25 and the linkage transmission shafts b3-19, the friction transmission belts 2-25 drive the linkage transmission shafts b3-19 to rotate when moving, the linkage transmission shafts b3-19 rotate to drive the linkage power gears 3-20 to rotate, the linkage power gears 3-20 rotate to drive the two internal thread rotating wheels 3-8 in a contact state, the two internal thread rotating wheels 3-8 rotate to drive the external thread shafts 3-21 to move upwards or downwards, when the external thread shafts 3-21 move upwards, the external thread shafts 3-21 drive the pressing blocks 3-22 to move, when the pressing blocks 3-22 move upwards to a limit position, the rack 2-6 is meshed with the special-shaped gear a2-3, the two internal thread rotating wheels 3-8 are gradually separated, at the moment, the external thread shafts 3-21 and the pressing blocks 3-22 are not limited by the internal thread rotating wheels 3-8, the pressing blocks 3-22 fall downwards and quickly under the limitation of the two mounting plates 1-7, the pressing blocks 3-22 fall to press steel materials clamped between the two pressing shafts 1-2, then the two internal thread rotating wheels 3-8 are gradually contacted and rotate under the action of the linkage power gear 3-20, the actual effect of the rotation of the reciprocating motion matched steel materials is that the steel materials automatically rotate 90 degrees after the pressing blocks 3-22 fall to press the steel materials, the two internal thread rotating wheels 3-8 separate the pressing blocks 3-22 to lose the limitation of falling after the pressing blocks 3-22 move upwards, and continues to reciprocate.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11, fig. 12, fig. 13, fig. 14, fig. 15, fig. 16, fig. 17, fig. 18, and the embodiment further describes the embodiment, where the automatic discharging mechanism 4 includes a discharging motor 4-1, a discharging motor shaft 4-2, a discharging belt 4-3, a discharging gear 4-4, a discharging rack 4-5, a rack connecting plate 4-6, a discharging return spring 4-7, a discharging return shaft 4-8, a discharging limit plate 4-9, a mounting plate a4-10, a discharging press block 4-11, a press block sliding plate 4-12, an inclined plate 4-13, and an inclined connecting plate 4-14, the discharging motor 4-1 is connected with the discharging motor shaft 4-2, two discharging motor shafts 4-2 are in friction connection with a discharging belt 4-3, a discharging gear 4-4 is connected with the discharging motor shaft 4-2, a discharging rack 4-5 is meshed with the discharging gear 4-4, a rack connecting plate 4-6 is connected with two discharging racks 4-5, a discharging reset spring 4-7 is sleeved on a discharging reset shaft 4-8 and limited on the rack connecting plate 4-6 and a mounting plate a4-10, a discharging limiting plate 4-9 is connected with the two discharging racks 4-5, a mounting plate a4-10 is in sliding connection with the discharging rack 4-5, a discharging pressing block 4-11 is connected with the discharging limiting plate 4-9, a pressing block sliding plate 4-12 is connected with the two mounting plates 1-7, an inclined plate 4-13 is connected with the pressing block sliding plate 4-12, the inclined connecting plates 4-14 are connected with the inclined plates 4-13, the discharging motor 4-1 is connected with the equipment mounting base plate 1-8, a discharging motor shaft 4-2 is connected with the equipment mounting base plate 1-8 through a bearing, the discharging reset shaft 4-8 is connected with the mounting plate a4-10 in a sliding manner, the mounting plate a4-10 is connected with the two equipment mounting side plates 1-5, the mounting plate a4-10 is connected with the equipment mounting base plate 1-8, the mounting plate a4-10 is connected with the equipment mounting plate 2-24, the discharging pressing block 4-11 is connected with the pressing block sliding plate 4-12 in a sliding manner, the inclined connecting plates 4-14 are connected with the equipment mounting base plate 1-8, the equipment can automatically output forged steel, the discharging motor 4-1 works to drive the discharging motor shaft 4-2 to rotate, the discharging motor shaft 4-2 drives the other discharging motor shaft 4-2 to rotate through the discharging belt 4-3, the discharging motor shaft 4-2 rotates to drive the discharging gear 4-4 to rotate, the two discharging gears 4-4 rotate to drive the two discharging racks 4-5 to move inwards or outwards, when the discharging gears move inwards, the two discharging racks 4-5 drive the discharging pressing block 4-11 to move through the discharging limiting plate 4-9, when the discharging pressing block 4-11 moves to a position between the two pressing shafts 1-2, steel clamped by the two pressing shafts 1-2 is pushed out, and the pushed steel is inclined down under the action of the inclined plate 4-13.

The sixth specific implementation mode:

next, the present embodiment will be described with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17 and 18, and the first embodiment will be further described with reference to the embodiment in which the pressing blocks 3 to 22 are made of high density alloy steel.

The working principle of the device is as follows: the equipment can clamp steel to be forged, the two handles 1-1 are pulled, the handles 1-1 drive the pressing shafts 1-2 to move outside the equipment, the pressing shafts 1-2 drive the spring connecting blocks 1-3 to move outside the equipment, the mounting side plates 1-5 and the spring connecting plates 1-6 limit the relative positions of the pressing shafts 1-2, the spring connecting blocks 1-3 press the pressure springs 1-4 to enable the pressure springs 1-4 to press the spring connecting plates 1-6, when the two pressing shafts 1-2 are pulled to have gaps, the steel to be forged is placed between the two pressing shafts 1-2, the pulling of the handles 1-1 is stopped, the two pressing shafts 1-2 extrude the steel under the action of the pressure springs 1-4 to enable the steel to be clamped, and the equipment can rotate the steel, the device can forge steel by a pressing block, a linkage motor 2-1 works, the linkage motor 2-1 works to drive a special-shaped gear a2-3 to rotate through a linkage motor 2-1, the special-shaped gear a2-3 rotates to drive a gear 2-4 to intermittently rotate by taking a gear shaft 2-5 as an axis, the gear 2-4 moves to drive a rack 2-6 to transversely move under the limitation of two rack limiting plates 2-7, when the rack 2-6 moves towards a belt b2-17 direction, the hinge plate 2-8 is driven to move by taking a hinge plate pulley 2-9 as a pivot, the rotating rod 2-11 is pressed to move towards a direction far away from the belt b2-17, a certain gap amount is reserved between the two hinge plate pulleys 2-9 and the hinge plate 2-8, and the movement obstacle of the hinge plate 2-9 to the hinge plate 2-8 when the hinge plate 2-8 rotates is avoided, the pressing rotating rod 2-11 rotates by taking the rotating shaft 2-12 as an axis, the other side of the pressing rotating rod 2-11 drives the hinged pressing plate 2-13 to press the pressing plate 2-14, the pressing plate 2-14 is pressed to drive the pressing shaft 1-2 to move towards, when the pressing shaft 1-2 moves upwards to the limit position, the special-shaped gear a2-3 is not engaged with the rack 2-6, the motor shaft 2-2 also drives the transmission shaft 2-16 to rotate by the belt a2-15 when rotating, the transmission shaft 2-16 rotates to drive the other transmission shaft 2-16 on the same side to rotate by the friction transmission belt 2-25, the transmission shaft 2-16 drives the transmission shaft 2-16 on the other side to rotate by the belt b2-17, at the moment, the four transmission shafts 2-16 rotate simultaneously, the friction transmission belt 2-25 drives the friction shaft 2-18 to rotate when moving along, the friction shaft 2-18 rotates to drive the connecting shaft 2-21 to rotate through the belt c2-20, the connecting shaft 2-21 rotates to drive the gear 2-22 to rotate, the gear 2-22 rotates to drive the special-shaped gear b2-23 on the pressing shaft 1-2 to rotate, the gear 2-22 is a quarter gear, the special-shaped gear b2-23 stops rotating after rotating for 90 degrees, at the moment, the pressing shaft 1-2 is at the limit position of upward movement, the pressing shaft 1-2 starts to move downwards due to the gravity influence of steel clamped by the pressing shaft 1-2 and the two pressing shafts 1-2, the gear 2-22 and the special-shaped gear b2-23 are not meshed, the equipment resets, the rack 2-6 returns to the initial position, the rack 2-6 also drives the linkage hinge plate a3-1 to move when moving, when the rack 2-6 moves towards the belt b2-17, the two linked hinged plates a3-1 move to drive the linked hinged plate b3-2 to move towards the direction far away from the center of the equipment under the limitation of the two slide rails 3-16, the two linked hinged plates b3-2 move to drive the two connecting plates a3-3 to move, the connecting plates a3-3 move to pull the linked blocks 3-5 through the linked springs 3-7, the two linked blocks 3-5 pull the two internally threaded rotating wheels 3-8 to separate through the shifting shafts 3-6, the shifting shafts 3-6 pull the internally threaded rotating wheels 3-8 to separate under the action of the grooves on the upper sides of the internally threaded rotating wheels 3-8 and move towards two sides, the connecting plates a3-3 also drive the sliding connecting plates 3-17 to move, and the sliding connecting plates 3-17 drive the limiting shafts 3-9, the limiting blocks 3-10 and the limiting springs to move along with 3-11, under the action of a limiting shaft 3-9, a limiting block 3-10 and a limiting spring 3-11, when the internally threaded rotating wheel 3-8 is separated, the two shifting shafts 3-6 can pull the two internally threaded rotating wheels 3-8 to move, the internally threaded rotating wheels 3-8 do transverse reciprocating motion in the motion of following the linkage hinge plate a3-1, namely the internally threaded rotating wheels 3-8 are opened to reciprocate after contacting, the linkage transmission shaft a3-18 is also driven to move when the friction transmission belt 2-25 moves, the linkage transmission shaft a3-18 rotates, the linkage transmission shaft a3-18 rotates to contribute to the friction connection relationship between the friction transmission belt 2-25 and the linkage transmission shaft b3-19, the linkage transmission shaft b3-19 rotates when the friction transmission belt 2-25 moves, the linkage transmission shaft b3-19 rotates to drive the linkage power gear 3-20 to rotate, the linkage power gear 3-20 rotates to drive the two internal thread rotating wheels 3-8 in a contact state to rotate, the two internal thread rotating wheels 3-8 rotate to drive the external thread shafts 3-21 to move upwards or downwards, when the external thread shafts 3-21 move upwards, the external thread shafts 3-21 drive the compression blocks 3-22 to move, when the compression blocks 3-22 move upwards to a limit position, the racks 2-6 are meshed with the special-shaped gear a2-3, the two internal thread rotating wheels 3-8 are gradually separated, at the moment, the external thread shafts 3-21 and the compression blocks 3-22 are not limited by the internal thread rotating wheels 3-8, the compression blocks 3-22 fall downwards and quickly under the limitation of the two mounting plates 1-7, the pressing blocks 3-22 fall to press steel clamped between the two pressing shafts 1-2, then the two internal thread rotating wheels 3-8 are gradually contacted and rotate under the action of the linkage power gears 3-20, the actual effect of the reciprocating motion matched with the rotation of the steel is that the steel automatically rotates for 90 degrees after the pressing blocks 3-22 fall to press the steel, the two internal thread rotating wheels 3-8 separate the pressing blocks 3-22 after the pressing blocks 3-22 move upwards to lose the limit of falling and continuously reciprocate, the device can automatically output the forged steel, the discharging motor 4-1 works to drive one discharging motor shaft 4-2 to rotate, and the discharging motor shaft 4-2 drives the other discharging motor shaft 4-2 to rotate through the discharging belt 4-3, the discharging motor shaft 4-2 rotates to drive the discharging gear 4-4 to rotate, the two discharging gears 4-4 rotate to drive the two discharging racks 4-5 to move inwards or outwards, when the discharging racks 4-5 move inwards, the two discharging racks 4-5 drive the discharging pressing block 4-11 to move through the discharging limiting plate 4-9, when the discharging pressing block 4-11 moves to a position between the two pressing shafts 1-2, steel clamped by the two pressing shafts 1-2 is pushed out, and the pushed steel tilts down under the action of the tilting plates 4-13.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (6)

1. The utility model provides a steel forging equipment for steelmaking, includes fixed establishment (1), automatic rotary mechanism (2), forges mechanism (3), automatic discharging mechanism (4), its characterized in that: fixing mechanism (1) be connected with automatic rotary mechanism (2), automatic rotary mechanism (2) are connected with forging mechanism (3), forging mechanism (3) are connected with fixing mechanism (1), automatic discharging mechanism (4) are connected with fixing mechanism (1), fixing mechanism (1) are connected with automatic discharging mechanism (4), automatic rotary mechanism (2) are connected with automatic discharging mechanism (4).

2. The steel forging apparatus for steelmaking as claimed in claim 1, wherein: the fixing mechanism (1) comprises a handle (1-1), a pressing shaft (1-2), a spring connecting block (1-3), a pressure spring (1-4), an equipment mounting side plate (1-5), a spring connecting plate (1-6), a mounting plate (1-7) and an equipment mounting bottom plate (1-8), wherein the handle (1-1) is connected with the pressing shaft (1-2), the pressing shaft (1-2) is connected with the spring connecting block (1-3), one side of the pressure spring (1-4) is connected with the spring connecting block (1-3) and the other side is connected with the spring connecting plate (1-6), the equipment mounting side plate (1-5) is connected with the pressing shaft (1-2) in a sliding manner, the spring connecting plate (1-6) is connected with the pressing shaft (1-2) in a sliding manner, the mounting plate (1-7) is connected with the pressing shaft (1-2) in a sliding mode, the equipment mounting bottom plate (1-8) is connected with the equipment mounting side plate (1-5), the spring connecting plate (1-6) is connected with the equipment mounting bottom plate (1-8), and the mounting plate (1-7) is connected with the equipment mounting bottom plate (1-8).

3. The steel forging apparatus for steelmaking as claimed in claim 1, wherein: the automatic rotating mechanism (2) comprises a linkage motor (2-1), a motor shaft (2-2), a special-shaped gear a (2-3), a gear (2-4), a gear shaft (2-5), a rack (2-6), a rack limiting plate (2-7), a hinged plate (2-8), a hinged plate pulley (2-9), a pulley shaft (2-10), a rotating rod (2-11), a rotating shaft (2-12), a hinged pressing plate (2-13), a pressing plate (2-14), a belt a (2-15), a transmission shaft (2-16), a belt b (2-17), a friction shaft (2-18), a bearing plate (2-19), a belt c (2-20), a connecting shaft (2-21), a gear (2-22), A special-shaped gear b (2-23), an equipment mounting plate (2-24) and a friction transmission belt (2-25), wherein a linkage motor (2-1) is connected with a motor shaft (2-2), the motor shaft (2-2) is connected with a special-shaped gear a (2-3), a gear (2-4) is connected with a gear shaft (2-5), the gear shaft (2-5) is connected with the equipment mounting plate (2-24) through a bearing, a rack (2-6) is meshed with the gear (2-4), a rack limiting plate (2-7) is connected with the rack (2-6) in a sliding manner, two hinged plates (2-8) are hinged with the rack (2-6), hinged plate pulleys (2-9) are connected with the hinged plates (2-8) through a friction manner, a pulley shaft (2-10) is connected with the hinged plate pulleys (2-9) through a bearing, the rotating rod (2-11) is connected with the hinged plate (2-8) in a sliding way, the rotating shaft (2-12) is connected with the rotating rod (2-11) by a bearing, the hinged compression plate (2-13) is hinged with the rotating rod (2-11), the compression plate (2-14) is hinged with the hinged compression plate (2-13), the belt a (2-15) is connected with the motor shaft (2-2) in a friction way, one transmission shaft (2-16) is connected with the belt a (2-15) in a friction way, the belt b (2-17) is connected with two transmission shafts (2-16) in a friction way, the friction shaft (2-18) is connected with the bearing plate (2-19) by a bearing, the bearing plate (2-19) is connected with the equipment mounting plate (2-24), and the belt c (2-20) is connected with the friction shaft (2-18) by a friction way, a connecting shaft (2-21) is in friction connection with a belt c (2-20), gears (2-22) are in friction connection with the connecting shaft (2-21), a special-shaped gear b (2-23) is connected with a pressing shaft (1-2), an equipment mounting plate (2-24) is connected with a linkage motor (2-1), a friction transmission belt (2-25) is in friction connection with a transmission shaft (2-16), a pulley shaft (2-10) is connected with the equipment mounting plate (2-24), a rotating shaft (2-12) is connected with an equipment mounting side plate (1-5), a pressing plate (2-14) is in sliding connection with the equipment mounting plate (2-24), the transmission shaft (2-16) is in bearing connection with the equipment mounting plate (2-24), and a friction shaft (2-18) is in friction connection with the friction transmission belt (2-25), the connecting shafts (2-21) are in bearing connection with the equipment installation side plates (1-5).

4. The steel forging apparatus for steelmaking as claimed in claim 1, wherein: the forging mechanism (3) comprises a linkage hinged plate a (3-1), a linkage hinged plate b (3-2), a connecting plate a (3-3), a linkage shaft (3-4), a linkage block (3-5), a shifting shaft (3-6), a linkage spring (3-7), an internal thread rotating wheel (3-8), a limiting shaft (3-9), a limiting block (3-10), a limiting spring (3-11), a reset connecting plate a (3-12), a reset connecting plate b (3-13), a reset shaft (3-14), a reset spring (3-15), a sliding rail (3-16), a sliding connecting plate (3-17), a linkage transmission shaft a (3-18), a linkage transmission shaft b (3-19), a linkage power gear (3-20), The device comprises an external thread shaft (3-21) and a pressing block (3-22), a linkage hinged plate a (3-1) is hinged with a linkage hinged plate b (3-2), the linkage hinged plate b (3-2) is connected with a connecting plate a (3-3), the connecting plate a (3-3) is in sliding connection with a linkage shaft (3-4), the linkage shaft (3-4) is connected with a linkage block (3-5), the linkage block (3-5) is connected with a shifting shaft (3-6), the shifting shaft (3-6) is in sliding connection with a groove on an internal thread rotating wheel (3-8), a linkage spring (3-7) is sleeved on the linkage shaft (3-4) and limited on the connecting plate a (3-3) and the linkage block (3-5), the upper sides of two internal thread rotating wheels (3-8) are meshed with a linkage power gear (3-20), the limiting shaft (3-9) is connected with the limiting block (3-10), the limiting block (3-10) is connected with the two internal thread rotating wheels (3-8) in a sliding way, the limiting spring (3-11) is sleeved on the limiting shaft (3-9) and limited on the limiting block (3-10) and the sliding connecting plate (3-17), the reset connecting plate a (3-12) is connected with the reset shaft (3-14), the reset connecting plate b (3-13) is connected with the reset shaft (3-14) in a sliding way, the reset spring (3-15) is sleeved on the reset shaft (3-14) and limited on the reset connecting plate a (3-12) and the reset connecting plate b (3-13), the slide rail (3-16) is connected with the sliding connecting plate (3-17) in a sliding way, and the sliding connecting plate (3-17) is connected with the limiting shaft (3-9) in a sliding way, the linkage transmission shaft a (3-18) is in friction connection with the belt b (2-17), the linkage transmission shaft b (3-19) is in friction connection with the belt b (2-17), the linkage power gear (3-20) is connected with the linkage transmission shaft b (3-19), the external thread shaft (3-21) is in threaded connection with the internal thread rotating wheel (3-8), the pressing block (3-22) is in bearing connection with the external thread shaft (3-21), the linkage hinge plate a (3-1) is in sliding connection with the equipment mounting plate (2-24), the linkage hinge plate b (3-2) is in sliding connection with the equipment mounting plate (2-24), the connecting plate a (3-3) is in sliding connection with the equipment mounting plate (2-24), and the two internal thread rotating wheels (3-8) are in sliding connection with the equipment mounting plate (2-24), the reset connecting plate a (3-12) is connected with the equipment mounting plate (2-24) in a sliding mode, the reset connecting plate b (3-13) is connected with the equipment mounting plate (2-24), the sliding rail (3-16) is connected with the equipment mounting plate (2-24), the sliding connecting plate (3-17) is connected with the equipment mounting plate (2-24) in a sliding mode, the linkage transmission shaft a (3-18) is connected with the equipment mounting plate (2-24) in a bearing mode, the linkage transmission shaft b (3-19) is connected with the equipment mounting plate (2-24) in a bearing mode, and the external threaded shaft (3-21) is connected with the equipment mounting plate (2-24) in a sliding mode.

5. The steel forging apparatus for steelmaking as claimed in claim 1, wherein: the automatic discharging mechanism (4) comprises a discharging motor (4-1), discharging motor shafts (4-2), discharging belts (4-3), discharging gears (4-4), discharging racks (4-5), rack connecting plates (4-6), discharging reset springs (4-7), discharging reset shafts (4-8), discharging limiting plates (4-9), mounting plates a (4-10), discharging pressing blocks (4-11), pressing block sliding plates (4-12), inclined plates (4-13) and inclined connecting plates (4-14), the discharging motor (4-1) is connected with the discharging motor shafts (4-2), the two discharging motor shafts (4-2) are in friction connection with the discharging belts (4-3), and the discharging gears (4-4) are connected with the discharging motor shafts (4-2), the discharging racks (4-5) are meshed with the discharging gears (4-4), the rack connecting plate (4-6) is connected with the two discharging racks (4-5), the discharging reset spring (4-7) is sleeved on the discharging reset shaft (4-8) and limited on the rack connecting plate (4-6) and the mounting plate a (4-10), the discharging limiting plate (4-9) is connected with the two discharging racks (4-5), the mounting plate a (4-10) is connected with the discharging racks (4-5) in a sliding way, the discharging pressing block (4-11) is connected with the discharging limiting plate (4-9), the pressing block sliding plate (4-12) is connected with the two mounting plates (1-7), the inclined plate (4-13) is connected with the pressing block sliding plate (4-12), the inclined connecting plate (4-14) is connected with the inclined plate (4-13), the discharging motor (4-1) is connected with the equipment mounting base plate (1-8), a discharging motor shaft (4-2) is connected with the equipment mounting base plate (1-8) through a bearing, the discharging reset shaft (4-8) is connected with the mounting plate a (4-10) in a sliding mode, the mounting plate a (4-10) is connected with the two equipment mounting side plates (1-5), the mounting plate a (4-10) is connected with the equipment mounting base plate (1-8), the mounting plate a (4-10) is connected with the equipment mounting plate (2-24), the discharging pressing block (4-11) is connected with the pressing block sliding plate (4-12) in a sliding mode, and the inclined connecting plate (4-14) is connected with the equipment mounting base plate (1-8).

6. The steel forging apparatus for steelmaking as claimed in claim 1, wherein: the pressing blocks (3-22) are made of alloy steel with high density.

Images