CN112692206A

CN112692206A - Forging machine capable of performing double-sided forging and heat preservation on workpiece

Info

Publication number: CN112692206A
Application number: CN202011578149.XA
Authority: CN
Inventors: 徐闻
Original assignee: Nanjing Lanxiner Technology Co ltd
Current assignee: Nanjing Lanxiner Technology Co ltd
Priority date: 2020-12-28
Filing date: 2020-12-28
Publication date: 2021-04-23

Abstract

The invention discloses a forging machine for double-sided forging and heat preservation of workpieces, which comprises a forging machine body, wherein a workpiece cavity with an upward opening is arranged in the forging machine body, a threaded shaft is rotatably connected to the inner wall of the lower side of the workpiece cavity, a sliding box is in threaded connection with the threaded shaft, the sliding box is in up-and-down sliding fit with the inner side wall of the workpiece cavity, and a clamping cavity with a forward opening and a left-and-right through opening is arranged in the sliding box; when the workpiece is forged, two side surfaces of the workpiece are directly forged, deformation of the workpiece during single-side forging is reduced, the sliding box is driven to slide up and down through the continuous forward and reverse rotating threaded shaft, the workpiece is driven to slide up and down, the left end surface and the right end surface of the workpiece are uniformly forged, heat generated by friction between the friction rod and the friction block is used for preserving heat of the workpiece, and the workpiece is prevented from being cooled in advance and the forging quality is prevented from being influenced.

Description

Forging machine capable of performing double-sided forging and heat preservation on workpiece

Technical Field

The invention relates to the related field of forging machines, in particular to a forging machine for double-sided forging and heat preservation of a workpiece.

Background

Traditional forging machine is forging the work piece when, to forging a surface of work piece, this kind of mode can make the work piece produce great deformation volume, later still need shape to the work piece, just can make the work piece carry out normal use, because the time of forging is longer for the work piece can cool off in advance at the in-process of processing, and then makes the effect of forging unobvious, and then has influenced the quality of forging.

The forging machine for double-sided forging and heat preservation of the workpiece, which is disclosed by the invention, can solve the problems.

Disclosure of Invention

In order to solve the problems, the forging machine for double-sided forging and heat preservation of workpieces is designed in the embodiment, the forging machine for double-sided forging and heat preservation of workpieces comprises a forging machine body, a workpiece cavity with an upward opening is arranged in the forging machine body, a threaded shaft is rotatably connected to the inner wall of the lower side of the workpiece cavity, a sliding box is in threaded connection with the threaded shaft, the sliding box is in up-and-down sliding fit with the inner wall of the workpiece cavity, a clamping cavity with a forward opening and a left-and-right through opening is arranged in the sliding box, a threaded rod is rotatably connected between the upper inner wall and the lower inner wall of the clamping cavity, a sliding clamping block is in threaded connection with the threaded rod, and the rear end face of the sliding clamping block abuts against the inner wall of the rear side; forge the organism and be equipped with two ascending slip chambeies of opening, two the slip chamber about placing of work piece chamber bilateral symmetry, two the slip chamber is close to all place from top to bottom on the inside wall in work piece chamber has set firmly two clutch blocks, the heat-conducting plate has set firmly respectively on the inside wall about the work piece chamber, the clutch block is close to the one end rigid coupling in the left and right sides in work piece chamber is corresponding on the heat-conducting plate, four all slide in the clutch block and be equipped with the friction bar, two the equal horizontal slip of slip intracavity is equipped with the linkage slide bar, keeps away from with two of one side the friction bar the one end rigid coupling in work piece chamber in the linkage slide bar is close to on the terminal surface in work piece chamber, two the upper end of linkage slide bar is located the upside and the rigid coupling of forging the organism have the hammer, two the linkage slide bar is kept away from the terminal surface in work piece chamber respectively with corresponding the slip chamber is kept Three thrust springs are fixedly arranged; place the work piece on centre gripping chamber downside inner wall, later the threaded rod rotates, and then press from both sides the work piece through the slip clamp splice, later the threaded shaft rotates and drives the slip case and slide from top to bottom, and then drive the work piece and slide from top to bottom, the linkage slide bar slides in the slip intracavity simultaneously, and then drive the forging hammer and slide, and then forge the gliding work piece from top to bottom through two forging hammers, the linkage slide bar drives the friction lever and slides when gliding, and then make the friction produce the heat between friction lever and the friction splice, and give off the work piece intracavity through the heat-conducting plate, and then improve the temperature in the work piece intracavity, prevent that the work piece from cooling too fast and influencing forged quality when forging.

Advantageously, the forging body is provided with a rack slot at the lower side of the sliding cavities, the rack slot is communicated with the two sliding cavities, a gear shaft is rotatably connected on the inner wall of the upper side of the rack groove, a linkage gear is fixedly connected at the lower end of the gear shaft, sliding racks are arranged on the front inner side wall and the rear inner side wall of the rack groove in a sliding mode, the two sliding racks are meshed with the linkage gear, return springs are fixedly arranged between the right end face of the sliding rack on the rear side and the inner wall of the right side of the rack groove and between the left end face of the sliding rack on the front side and the inner wall of the left side of the rack groove, the lower ends of the two linkage slide bars are located in the rack groove, the lower end of the linkage slide bar on the left side is fixedly connected to the upper end face of the sliding rack on the rear side, and the lower end of the linkage slide bar on the right side is fixedly connected to the upper end face of the sliding rack on the front; the gear shaft rotates, and then drives the sliding rack to oppositely slide through the linkage gear, and further drives the two linkage slide bars to oppositely slide, so as to drive the two forging hammers to oppositely slide, and further simultaneously forge the left end face and the right end face of the workpiece.

Beneficially, a worm wheel cavity is formed in the sliding box on the upper side of the clamping cavity, the upper end of the threaded rod is located in the worm wheel cavity and fixedly connected with a linkage worm wheel, a linkage worm is rotatably connected to the inner wall of the front side of the worm wheel cavity, and the linkage worm is meshed with the linkage worm wheel; the linkage worm rotates, and then drives the threaded rod through the linkage worm wheel and rotates, and then presss from both sides the work piece tightly through the slip clamp splice, because the auto-lock nature between linkage worm wheel, the linkage worm, and then prevents that the work piece from forging the removal, influencing forging effect.

Beneficially, a power cavity is arranged on the lower side of the workpiece cavity in the forging machine body, a synchronous rotating shaft is rotatably connected between the left inner side wall and the right inner side wall of the power cavity, two incomplete bevel gears are fixedly connected to the left inner side wall and the right inner side wall of the synchronous rotating shaft, the upper end of the gear shaft is located in the power cavity and fixedly connected with a connecting bevel gear, a positioning shaft is rotatably connected to the inner wall of the upper side of the power cavity, a driving pulley and a direction changing bevel gear are fixedly connected to the positioning shaft, the direction changing bevel gear is located on the lower side of the driving pulley, the lower side of the threaded shaft is located in the power cavity and fixedly connected with a driven pulley; the synchronous rotating shaft rotates, and then drives the positioning shaft to rotate forwards and backwards through the meshing of the two incomplete bevel gears and the turning bevel gear respectively, and then drives the synchronous belt to rotate through the driving belt wheel, and then drives the threaded shaft to rotate through the driven belt wheel, and then drives the sliding box to slide up and down.

Beneficially, a power motor is fixedly arranged on the inner wall of the rear side of the power cavity, a power output shaft is dynamically connected to the front end face of the power motor, a sliding worm is connected to the power output shaft through a spline, a spring cavity with a backward opening is arranged in the sliding worm, the power output shaft is located in the spring cavity, an electromagnetic spring is fixedly arranged between the front end face of the power output shaft and the inner wall of the front side of the spring cavity, a transmission bevel gear is fixedly connected to the front end of the sliding worm, and a linkage bevel gear is fixedly connected to the left side of the incomplete bevel gear on the left side of the synchronous rotating shaft; and starting the power motor, driving the sliding worm to rotate through the power output shaft, driving the linkage bevel gear to rotate through the transmission bevel gear, and driving the synchronous rotating shaft to rotate.

Beneficially, a transmission spline shaft is rotatably connected to the inner wall of the upper side of the power cavity at the rear side of the threaded shaft, a transmission worm wheel is fixedly connected to the lower end of the transmission spline shaft, a linkage cavity is arranged in the sliding box at the rear side of the clamping cavity, the linkage cavity is communicated with the worm wheel cavity, a linkage shaft sleeve is rotatably connected to the inner wall of the lower side of the linkage cavity, an upper end spline of the transmission spline shaft is connected in the linkage shaft sleeve, a driving bevel gear is fixedly connected to the upper end of the linkage shaft sleeve, a driven bevel gear is fixedly connected to the rear end of the linkage worm, and the driven bevel gear is meshed with the driving bevel gear; the sliding worm rotates and simultaneously drives the transmission worm wheel to rotate, then the transmission spline shaft drives the linkage shaft sleeve to rotate, and then the driving bevel gear drives the driven bevel gear to rotate, and then the linkage worm is driven to rotate.

The invention has the beneficial effects that: when the workpiece is forged, two side surfaces of the workpiece are directly forged, deformation of the workpiece during single-side forging is reduced, the sliding box is driven to slide up and down through the continuous forward and reverse rotating threaded shaft, the workpiece is driven to slide up and down, the left end surface and the right end surface of the workpiece are uniformly forged, heat generated by friction between the friction rod and the friction block is used for preserving heat of the workpiece, and the workpiece is prevented from being cooled in advance and the forging quality is prevented from being influenced.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view showing the overall structure of a forging machine for double-side forging and heat-insulating a workpiece according to the present invention.

FIG. 2 is a schematic view of the structure A-A of FIG. 1;

FIG. 3 is a schematic diagram of B-B of FIG. 1;

FIG. 4 is a schematic diagram of the structure of C-C in FIG. 1;

fig. 5 is a schematic diagram of the structure of D-D in fig. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1 to 5, for the sake of convenience of description, the following orientations are now defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The forging machine comprises a forging machine body 11, a workpiece cavity 33 with an upward opening is arranged in the forging machine body 11, a threaded shaft 53 is rotatably connected to the inner wall of the lower side of the workpiece cavity 33, a sliding box 37 is in threaded connection with the threaded shaft 53, the sliding box 37 is in up-and-down sliding fit with the inner side wall of the workpiece cavity 33, a clamping cavity 39 with a forward opening and a left-and-right through opening is arranged in the sliding box 37, a threaded rod 34 is rotatably connected between the upper inner wall and the lower inner wall of the clamping cavity 39, a sliding clamping block 40 is in threaded connection with the threaded rod 34, and the rear end face of the sliding clamping block 40 is abutted against the inner wall of the rear side of the clamping cavity 39; the forging machine is characterized in that two sliding cavities 12 with upward openings are arranged in the forging machine body 11, the two sliding cavities 12 are symmetrically arranged on the left and right of the workpiece cavity 33, the two sliding cavities 12 are close to the inner side wall of the workpiece cavity 33, two friction blocks 30 are arranged on the upper portion and the lower portion of the inner side wall of the workpiece cavity 33, heat conducting plates 32 are arranged on the left and right inner side walls of the workpiece cavity 33, one ends of the friction blocks 30 close to the workpiece cavity 33 are fixedly connected to the heat conducting plates 32 corresponding to the left and right sides, friction rods 31 are arranged in the four friction blocks 30 in a sliding mode, linkage slide rods 15 are arranged in the two sliding cavities 12 in a sliding mode, one ends of the two friction rods 31 on the same side, far away from the workpiece cavity 33, are fixedly connected to the end face, close to the workpiece cavity 33, of the linkage slide rods 15 are arranged on the upper side of the, three thrust springs 13 are fixedly arranged in a linear array and vertically arranged between the end surfaces of the two linkage slide bars 15 far away from the workpiece cavity 33 and the corresponding inner side walls of the slide cavity 12 far away from the workpiece cavity 33; the workpiece is placed on the inner wall of the lower side of the clamping cavity 39, then the threaded rod 34 is rotated, the workpiece is clamped tightly through the sliding clamping block 40, then the threaded shaft 53 rotates to drive the sliding box 37 to slide up and down, further the workpiece is driven to slide up and down, meanwhile the linkage sliding rod 15 slides in the sliding cavity 12, further the forging hammer 41 is driven to slide, further the workpiece sliding up and down is forged through the two forging hammers 41, the linkage sliding rod 15 drives the friction rod 31 to slide while sliding, further the friction between the friction rod 31 and the friction block 30 generates heat, and the heat is dissipated into the workpiece cavity 33 through the heat conduction plate 32, further the temperature in the workpiece cavity 33 is improved, and the workpiece is prevented from being cooled too fast to affect the forging quality when being forged.

Advantageously, the forging block 11 is provided with a rack slot 16 in the lower side of the sliding cavity 12, the rack slot 16 is communicated with the two sliding cavities 12, a gear shaft 24 is rotatably connected to the inner wall of the upper side of the rack slot 16, a linkage gear 23 is fixedly connected to the lower end of the gear shaft 24, sliding racks 20 are slidably arranged on the front inner side wall and the rear inner side wall of the rack groove 16, the two sliding racks 20 are engaged with the linkage gear 23, a return spring 17 is fixedly arranged between the right end face of the sliding rack 20 on the rear side and the right inner wall of the rack groove 16 and between the left end face of the sliding rack 20 on the front side and the left inner wall of the rack groove 16, the lower ends of the two linkage slide bars 15 are located in the rack groove 16, the lower end of the linkage slide bar 15 on the left side is fixedly connected to the upper end face of the sliding rack 20 on the rear side, and the lower end of the linkage slide bar 15 on the right side is fixedly connected to the upper end face of the sliding rack 20 on the front side; the gear shaft 24 rotates, and the linked gear 23 drives the sliding racks 20 to slide oppositely, and further drives the two linked sliding rods 15 to slide oppositely, so as to drive the two forging hammers 41 to slide oppositely, and further simultaneously forge the left and right end faces of the workpiece.

Advantageously, a worm wheel cavity 35 is arranged in the sliding box 37 at the upper side of the clamping cavity 39, the upper end of the threaded rod 34 is positioned in the worm wheel cavity 35 and fixedly connected with a linkage worm wheel 36, a linkage worm 38 is rotatably connected to the inner wall of the front side of the worm wheel cavity 35, and the linkage worm 38 is meshed with the linkage worm wheel 36; the linkage worm 38 rotates, the linkage worm wheel 36 drives the threaded rod 34 to rotate, and the workpiece is clamped through the sliding clamping block 40, and due to the self-locking property between the linkage worm wheel 36 and the linkage worm 38, the workpiece is prevented from moving in a forging mode, and the forging effect is prevented from being influenced.

Beneficially, a power cavity 14 is arranged in the forging machine body 11 at the lower side of the workpiece cavity 33, a synchronous rotating shaft 26 is rotatably connected between the left inner side wall and the right inner side wall of the power cavity 14, two incomplete bevel gears 21 are fixedly connected to the synchronous rotating shaft 26 at the left and right sides, the upper end of the gear shaft 24 is located in the power cavity 14 and is fixedly connected with a connecting bevel gear 25, a positioning shaft 28 is rotatably connected to the inner wall of the upper side of the power cavity 14, a driving pulley 29 and a direction-changing bevel gear 27 are fixedly connected to the positioning shaft 28, the direction-changing bevel gear 27 is located at the lower side of the driving pulley 29, the lower side of the threaded shaft 53 is located in the power cavity 14 and is fixedly connected with a driven pulley 49, and the driven pulley 49 is connected with; the synchronous rotating shaft 26 rotates, and then the two incomplete bevel gears 21 are respectively meshed with the direction-changing bevel gear 27 to drive the positioning shaft 28 to rotate forwards and backwards, and then the driving belt 29 drives the synchronous belt 22 to rotate, and then the driven belt 49 drives the threaded shaft 53 to rotate, and then the sliding box 37 is driven to slide up and down.

Beneficially, a power motor 42 is fixedly arranged on the inner wall of the rear side of the power cavity 14, a power output shaft 48 is dynamically connected to the front end face of the power motor 42, a sliding worm 45 is connected to the power output shaft 48 through a spline, a spring cavity 47 with a backward opening is arranged in the sliding worm 45, the power output shaft 48 is located in the spring cavity 47, an electromagnetic spring 46 is fixedly arranged between the front end face of the power output shaft 48 and the inner wall of the front side of the spring cavity 47, a transmission bevel gear 19 is fixedly connected to the front end of the sliding worm 45, and a linkage bevel gear 18 is fixedly connected to the left side of the incomplete bevel gear 21 on the left side of the synchronous rotating shaft 26; the power motor 42 is started, and the sliding worm 45 is driven to rotate through the power output shaft 48, and the linkage bevel gear 18 is driven to rotate through the transmission bevel gear 19, and the synchronous rotating shaft 26 is driven to rotate.

Beneficially, a transmission spline shaft 44 is rotatably connected to the inner wall of the upper side of the power cavity 14 at the rear side of the threaded shaft 53, a transmission worm gear 43 is fixedly connected to the lower end of the transmission spline shaft 44, a linkage cavity 51 is arranged in the sliding box 37 at the rear side of the clamping cavity 39, the linkage cavity 51 is communicated with the worm gear cavity 35, a linkage shaft sleeve 50 is rotatably connected to the inner wall of the lower side of the linkage cavity 51, the upper end of the transmission spline shaft 44 is splined to the linkage shaft sleeve 50, a driving bevel gear 56 is fixedly connected to the upper end of the linkage shaft sleeve 50, a driven bevel gear 54 is fixedly connected to the rear end of the linkage worm 38, and the driven bevel gear 54 is meshed with the driving bevel gear 56; the sliding worm 45 rotates and drives the transmission worm wheel 43 to rotate, and further drives the linkage shaft sleeve 50 to rotate through the transmission spline shaft 44, and further drives the driven bevel gear 54 to rotate through the driving bevel gear 56, and further drives the linkage worm 38 to rotate.

The following detailed description of the steps of a forging machine for double-sided forging and holding a workpiece is provided with reference to fig. 1 to 5:

initially, the sliding clamping block 40 is at the upper limit position, the electromagnetic spring 46 is in a compressed state, the sliding worm 45 is meshed with the transmission worm wheel 43, the transmission bevel gear 19 is not meshed with the linkage bevel gear 18, the friction rod 31 is completely positioned in the friction block 30, the front sliding rack 20 is at the right limit position, and the rear sliding rack 20 is at the left limit position;

placing a workpiece on the inner wall of the lower side of the clamping cavity 39, starting the power motor 42, further driving the sliding worm 45 to rotate through the power output shaft 48, driving the transmission worm wheel 43 to rotate through the rotation of the sliding worm 45, further driving the linkage shaft sleeve 50 to rotate through the transmission spline shaft 44, further driving the driven bevel gear 54 to rotate through the driving bevel gear 56, further driving the linkage worm 38 to rotate, further driving the threaded rod 34 to rotate through the linkage worm wheel 36, further driving the sliding clamping block 40 to slide downwards to clamp the workpiece, and further preventing the workpiece from forging and moving due to the self-locking property between the linkage worm wheel 36 and the linkage worm 38, so that the forging effect is influenced; then the electromagnetic spring 46 is electrified and extended to drive the sliding worm 45 to slide forwards, so that the sliding worm 45 is disengaged from the transmission worm wheel 43, meanwhile, the transmission bevel gear 19 is engaged with the linkage bevel gear 18, and the transmission bevel gear 19 drives the linkage bevel gear 18 to rotate, so that the synchronous rotating shaft 26 is driven to rotate;

when the incomplete bevel gear 21 on the left side is meshed with the engaging bevel gear 25, the engaging bevel gear 25 drives the gear shaft 24 to rotate, the linkage gear 23 drives the two sliding racks 20 to oppositely slide, the two linkage sliding rods 15 are further driven to oppositely slide, the two forging hammers 41 are further driven to oppositely slide, the left end face and the right end face of the workpiece are simultaneously forged, and when the incomplete bevel gear 21 is not meshed with the engaging bevel gear 25, the sliding racks 20 are restored to the initial state under the elastic force action of the thrust spring 13 and the return spring 17, and the left end face and the right end face of the workpiece are repeatedly forged;

the linkage sliding rod 15 drives the friction rod 31 to slide while sliding, so that heat is generated by friction between the friction rod 31 and the friction block 30 and is dissipated into the workpiece cavity 33 through the heat conducting plate 32, the temperature in the workpiece cavity 33 is further increased, and the phenomenon that the forging quality is influenced by too fast cooling of the workpiece during forging is prevented;

when the two incomplete bevel gears 21 are respectively meshed with the direction-changing bevel gear 27, the direction-changing bevel gear 27 is driven to continuously rotate in a forward direction and a reverse direction, the positioning shaft 28 is driven to rotate in a forward direction and a reverse direction, the synchronous belt 22 is driven to rotate through the driving belt wheel 29, the threaded shaft 53 is driven to rotate through the driven belt wheel 49, the sliding box 37 is driven to slide up and down, and the workpiece is forged in a reciprocating manner up and down;

after the forging is finished, the electromagnetic spring 46 is powered off to restore the initial state, meanwhile, the power motor 42 rotates reversely, and then the workpiece is taken out.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. The utility model provides a forging machine that two-sided forging was beaten and carried out heat preservation to the work piece, includes the forging machine body, its characterized in that: a workpiece cavity with an upward opening is arranged in the forging machine body, a threaded shaft is rotatably connected to the inner wall of the lower side of the workpiece cavity, a sliding box is in threaded connection with the threaded shaft, the sliding box is in up-and-down sliding fit with the inner side wall of the workpiece cavity, a clamping cavity with a forward opening and a left-and-right through opening is arranged in the sliding box, a threaded rod is rotatably connected between the upper inner side wall and the lower inner side wall of the clamping cavity, a sliding clamping block is in threaded connection with the threaded rod, and the rear end face of the sliding clamping block abuts against the inner wall of the; forge the organism and be equipped with two ascending slip chambeies of opening, two the slip chamber about placing of work piece chamber bilateral symmetry, two the slip chamber is close to all place from top to bottom on the inside wall in work piece chamber has set firmly two clutch blocks, the heat-conducting plate has set firmly respectively on the inside wall about the work piece chamber, the clutch block is close to the one end rigid coupling in the left and right sides in work piece chamber is corresponding on the heat-conducting plate, four all slide in the clutch block and be equipped with the friction bar, two the equal horizontal slip of slip intracavity is equipped with the linkage slide bar, keeps away from with two of one side the friction bar the one end rigid coupling in work piece chamber in the linkage slide bar is close to on the terminal surface in work piece chamber, two the upper end of linkage slide bar is located the upside and the rigid coupling of forging the organism have the hammer, two the linkage slide bar is kept away from the terminal surface in work piece chamber respectively with corresponding the slip chamber is kept Three thrust springs are fixedly arranged.

2. The forging machine for double-sided forging and keeping a workpiece warm as recited in claim 1, wherein: the forging machine in the downside in slip chamber is equipped with the rack groove, rack groove and two slip chamber intercommunication, rotate on the rack groove upside inner wall and be connected with the gear shaft, gear shaft lower extreme rigid coupling has linkage gear, all slide on the inside wall around the rack groove and be equipped with slip rack, two slip rack all with linkage gear engagement, the rear side the right-hand member face of slip rack with between the right side inner wall of rack groove, the front side the left end face of slip rack with all set firmly reset spring, two between the left side inner wall of rack groove the lower extreme of linkage slide bar all is located in the rack groove, the left side the lower extreme rigid coupling of linkage slide bar is in the rear side on the up end of slip rack, the right side the lower extreme rigid coupling of linkage slide bar in the front side on the up end of slip rack.

3. The forging machine for double-sided forging and keeping a workpiece warm as recited in claim 2, wherein: the upper side of the clamping cavity in the sliding box is provided with a worm wheel cavity, the upper end of the threaded rod is located in the worm wheel cavity and fixedly connected with a linkage worm wheel, the inner wall of the front side of the worm wheel cavity is rotatably connected with a linkage worm, and the linkage worm is meshed with the linkage worm wheel.

4. A forging machine for double-sided forging and keeping a workpiece warm as set forth in claim 3, wherein: the forging machine in the downside in work piece chamber is equipped with the power chamber, rotate between the inside wall about the power chamber and be connected with synchronous rotating shaft, the rigid coupling of placing about in the synchronous rotating shaft has two incomplete bevel gears, the upper end of gear shaft is located power intracavity and rigid coupling have linking bevel gear, rotate on the power chamber upside inner wall and be connected with the location axle, the epaxial rigid coupling of location has driving pulley, diversion bevel gear is located driving pulley's downside, the downside of screw thread axle is located power intracavity and rigid coupling have driven pulleys, driven pulleys with driving pulley passes through synchronous belt and connects.

5. The forging machine for double-sided forging and keeping a workpiece warm as recited in claim 4, wherein: the power cavity rear side inner wall is fixedly provided with a power motor, the power motor front end face is provided with a power output shaft in a power connection mode, the power output shaft is provided with a sliding worm in a spline connection mode, a spring cavity with a backward opening is arranged in the sliding worm, the power output shaft is located in the spring cavity, an electromagnetic spring is fixedly arranged between the power output shaft front end face and the spring cavity front side inner wall, the front end of the sliding worm is fixedly connected with a transmission bevel gear, and the synchronous rotating shaft is fixedly connected with a linkage bevel gear on the left side of the incomplete bevel gear.

6. The forging machine for double-sided forging and keeping a workpiece warm as recited in claim 5, wherein: the power cavity upside inner wall in the rear side rotation of threaded shaft is connected with the transmission integral key shaft, the lower extreme rigid coupling of transmission integral key shaft has the transmission worm wheel, the sliding box in the rear side in centre gripping chamber is equipped with the linkage chamber, the linkage chamber with worm wheel chamber intercommunication, it is connected with the linkage axle sleeve to rotate on the inboard wall of linkage chamber downside, the upper end splined connection of transmission integral key shaft in the linkage axle sleeve, linkage axle sleeve upper end rigid coupling has initiative bevel gear, the rear end rigid coupling of linkage worm has driven bevel gear, driven bevel gear with the meshing of initiative bevel gear.