阅读说明：本技术 一种碳生产用加压成型装置 (Carbon production is with pressure forming device ) 是由 于春 于 2021-09-17 设计创作，主要内容包括：本发明公开了一种碳生产用加压成型装置,涉及碳生产技术领域,包括底座、第一传动带、第二传动带、齿轮带、金属传动带,所述底座的顶部设置有原料传送箱,所述原料传送箱的侧面固定连接有加压成型箱。该碳生产用加压成型装置,当主动轴转动时,通过第一传动槽和第一传动块的传动带动主动轮跟随主动轴进行转动,另外通过主动轮、金属传动带以及从动轮之间的传动带动从动轮转动,通过第二传动槽和第二传动块之间的传动带动从动轴旋转,利用从动轴带动凸轮旋转,通过凸轮的旋转挤压按压柱使得按压柱以及切断刀向下移动,同时通过弹簧推动切断刀以及按压柱向上移动,实现了对加压成型后的碳棒进行切断的功能。(The invention discloses a compression molding device for carbon production, and relates to the technical field of carbon production. This pressurization forming device is used in carbon production, when the driving shaft rotates, the transmission through first transmission groove and first transmission piece drives the action wheel and follows the driving shaft and rotate, in addition through the action wheel, metal transmission belt and from the transmission drive between the driving wheel rotate, it is rotatory to drive the driven shaft through the transmission between second transmission groove and the second transmission piece, it is rotatory to utilize the driven shaft to drive the cam, make through the rotatory extrusion pressing post of cam and press post and cut off the sword downstream, promote the cut off sword and press the post rebound through the spring simultaneously, the function of cutting off has been realized carrying out to the carbon rod after the pressure forming.)

1. The utility model provides a carbon production is with pressure forming device, includes base (1), first drive belt (15), second drive belt (18), gear area (27), metal drive belt (39), its characterized in that: the top of base (1) is provided with raw material conveying box (2), the side fixedly connected with pressurization forming box (3) of raw material conveying box (2), the top surface of base (1) and the one end that is located pressurization forming box (3) are provided with transport mechanism (10), the top surface of base (1) and the top that is located transport mechanism (10) are provided with and cut off case (9), the side of cutting off case (9) is provided with draw-out box (20), the inside of cutting off case (9) is seted up speed governing chamber (21), the inside of cutting off case (9) is seted up shrink chamber (29), the bottom fixedly connected with spring (31) of shrink chamber (29) inner chamber, the top fixedly connected with of spring (31) presses post (32), the bottom surface fixedly connected with cutting off knife (34) of pressing post (32), the one end of cutting off knife (34) extends to the bottom of cutting off case (9), the top end of the pressing column (32) is movably sleeved to an inner cavity of a speed regulation chamber (21) and is connected with a ball (33) in a clamped mode, the inner cavity of the speed regulation chamber (21) is connected with a driven shaft (25) in a rotating mode, a second transmission groove (42) is formed in the surface of the driven shaft (25), a cam (30) is sleeved on the surface of the driven shaft (25) in a fixed mode, the side face of the cam (30) is in contact with the surface of the ball (33), the inner cavity of the speed regulation chamber (21) is connected with a first bidirectional screw rod (22) in a rotating mode, the inner cavity of the speed regulation chamber (21) is connected with a second bidirectional screw rod (23) in a rotating mode, the inner cavity of the speed regulation chamber (21) is connected with a driving shaft (24) in a rotating mode, a first transmission groove (37) is formed in the surface of the driving shaft (24), first movable blocks (35) are respectively sleeved at the two ends of the first bidirectional screw rod (22) in a threaded mode, and are respectively sleeved with the driving shaft (24) in a movable mode, the inner sides of the two first movable blocks (35) are respectively rotatably connected with a driving wheel (36), the two driving wheels (36) are respectively movably sleeved with a driving shaft (24), the inner walls of the two driving wheels (36) are respectively and fixedly connected with first transmission blocks (38), one end of each first transmission block (38) extends to the inner cavity of each first transmission groove (37), the two ends of each second bidirectional screw rod (23) are respectively and threadedly sleeved with second movable blocks (40), the two second movable blocks (40) are respectively and movably sleeved with a driven shaft (25), the inner sides of the two second movable blocks (40) are respectively and rotatably connected with driven wheels (41), the two driven wheels (41) are respectively and movably sleeved with the driven shaft (25), the two inner walls of the driven wheels (41) are respectively and fixedly connected with second transmission blocks (43), one ends of the second transmission blocks (43) extend to the inner cavities of the second transmission grooves (42), the side surfaces of the metal transmission belt (39) are respectively attached to the inner side surfaces of the driving wheel (36) and the driven wheel (41).

2. The press molding apparatus for carbon production according to claim 1, wherein: the inner cavity of the raw material conveying box (2) is rotatably connected with a second spiral conveying rod (6), the inner wall of the raw material conveying box (2) is provided with a heating ring (7), the top of the raw material conveying box (2) is provided with a discharging barrel (4), the inner cavity of the discharging barrel (4) is rotatably connected with a first spiral conveying rod (5), the side surface of the first spiral conveying rod (5) is fixedly connected with a scraper (16), the side surface of the scraper (16) is attached to the inner wall of the discharging barrel (4), the top end of a rotating shaft of the first spiral conveying rod (5) extends to the top of the discharging barrel (4) and is fixedly sleeved with a helical gear (12), the top of the discharging barrel (4) is provided with a support frame (8), the top of the support frame (8) is rotatably connected with a transmission shaft (11), the middle part of the transmission shaft (11) is fixedly sleeved with another helical gear (12), two helical gear (12) intermeshing, the one end of transmission shaft (11) extends to one side of support frame (8) and fixed the cover and has connect first belt pulley (13), the other end of transmission shaft (11) extends to the opposite side of support frame (8) and fixed the cover and has connect second belt pulley (17).

3. The press molding apparatus for carbon production according to claim 1, wherein: the bottom of base (1) is provided with water storage tank (19), the side fixedly connected with of water storage tank (19) absorbs water pipe (53), the one end that absorbs water pipe (53) extends to the inner chamber of draw-in box (20), the middle part that absorbs water pipe (53) is provided with second check valve (54).

4. The press molding apparatus for carbon production according to claim 1, wherein: the utility model discloses a pressure forming tank, including pressurization forming tank (3), cooling tank (19), top fixedly connected with stand-off pipe (46) of pressurization forming tank (3), the one end in pressurization forming tank (44) is linked together with the inner chamber of raw materials conveying case (2), cooling tank (45) have been seted up to the inside of pressurization forming tank (3), the top fixedly connected with back flow (46) of pressurization forming tank (3), the one end of back flow (46) extends to the inner chamber of cooling tank (45), the other end of back flow (46) extends to the inner chamber of water storage box (19), the top fixedly connected with aqueduct (51) of pressurization forming tank (3), the one end of aqueduct (51) extends to the inner chamber of cooling tank (45), the other end of aqueduct (51) extends to the inner chamber of suction box (20), the middle part of aqueduct (51) is provided with first check valve (52).

5. The press molding apparatus for carbon production according to claim 1, wherein: one end of the driving shaft (24) extends to the outside of the cutting box (9) and is fixedly sleeved with another second belt pulley (17), and the two second belt pulleys (17) are in transmission connection through a second transmission belt (18).

6. The press molding apparatus for carbon production according to claim 1, wherein: the fixed cover of one end of driving shaft (24) has connect carousel (47), the side of carousel (47) is rotated and is connected with connecting rod (48), the one end of connecting rod (48) is rotated and is connected with lift post (49), the one end activity of lift post (49) is cup jointed to inner chamber and fixedly connected with piston (50) of pumping box (20), the side of piston (50) is laminated mutually with the inner wall of pumping box (20).

7. The press molding apparatus for carbon production according to claim 1, wherein: the one end of first bidirectional screw (22) extends to the outside of cut-off box (9) and fixed the cover and has connect spur gear (26), the one end of first bidirectional screw (22) is provided with knob (28), the one end of second bidirectional screw (23) extends to the outside of cut-off box (9) and fixed another spur gear (26) of having cup jointed, two spur gear (26) are through gear belt (27) transmission connection.

8. The press molding apparatus for carbon production according to claim 1, wherein: the top fixed mounting of base (1) has servo motor (14), the one end of servo motor (14) output shaft and the pivot fixed connection of second spiral material conveying pole (6), another first belt pulley (13) has been cup jointed to the side of servo motor (14) output shaft fixedly, two first belt pulley (13) are through first drive belt (15) transmission connection.

9. The press molding apparatus for carbon production according to claim 2, wherein: the front of putting feed cylinder (4) articulates there is sealing door (55), the front of putting feed cylinder (4) is provided with transparent window (56).

10. The press molding apparatus for carbon production according to claim 1, wherein: the side of the first transmission block (38) is attached to the inner wall of the first transmission groove (37), and the side of the second transmission block (43) is attached to the inner wall of the second transmission groove (42).

Technical Field

The invention relates to the technical field of carbon production, in particular to a compression molding device for carbon production.

Background

The charcoal generally refers to charcoal, and is a dark brown or black porous solid fuel remained after wood or wood raw materials are subjected to incomplete combustion or pyrolysis under the condition of air isolation, along with the increasing demand of the charcoal, a machine for producing the charcoal appears, the charcoal does not need to be produced in an earth kiln, and the charcoal needs to be subjected to a pressure forming step during the production of the charcoal, so that loose carbon powder is extruded and formed into a carbon rod.

However, the carbon rod produced by the existing pressure forming device for carbon production is cut by utilizing the self weight of the carbon rod, the uniformity of the length of the carbon rod cannot be ensured, and certain influence is exerted on the sale and the packaging of the carbon rod, so that the pressure forming device for carbon production is provided.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a compression molding device for carbon production, which solves the problems in the background technology.

In order to achieve the purpose, the invention is realized by the following technical scheme: a pressure forming device for carbon production comprises a base, a first transmission belt, a second transmission belt, a gear belt and a metal transmission belt, wherein a raw material conveying box is arranged at the top of the base, a pressure forming box is fixedly connected to the side surface of the raw material conveying box, a conveying mechanism is arranged at one end of the top surface of the base, a cutting box is arranged at the top surface of the base and above the conveying mechanism, a water pumping box is arranged at the side surface of the cutting box, a speed regulating chamber is arranged inside the cutting box, a contraction chamber is arranged inside the cutting box, a spring is fixedly connected to the bottom of the inner cavity of the contraction chamber, a pressing column is fixedly connected to the top end of the spring, a cutting knife is fixedly connected to the bottom surface of the pressing column, one end of the cutting knife extends to the bottom of the cutting box, the top end of the pressing column is movably sleeved to the inner cavity of the speed regulating chamber, and balls are clamped in the inner cavity of the speed regulating chamber, the inner cavity of the speed regulation chamber is rotatably connected with a driven shaft, the surface of the driven shaft is provided with a second transmission groove, the surface of the driven shaft is fixedly sleeved with a cam, the side surface of the cam is contacted with the surface of a ball, the inner cavity of the speed regulation chamber is rotatably connected with a first bidirectional screw rod, the inner cavity of the speed regulation chamber is rotatably connected with a second bidirectional screw rod, the inner cavity of the speed regulation chamber is rotatably connected with a driving shaft, the surface of the driving shaft is provided with a first transmission groove, two ends of the first bidirectional screw rod are respectively in threaded sleeve connection with a first movable block, the two first movable blocks are respectively in movable sleeve connection with the driving shaft, the inner sides of the two first movable blocks are respectively rotatably connected with driving wheels, the two driving wheels are respectively in movable sleeve connection with the driving shaft, the inner walls of the two driving wheels are fixedly connected with first transmission blocks, one end of each first transmission block extends to the inner cavity of the first transmission groove, the both ends of second bidirectional screw rod have been cup jointed the second movable block, two respectively the second movable block cup joints with the driven shaft activity respectively, two the inboard of second movable block rotates respectively to be connected with from the driving wheel, two cup joint with the driven shaft activity respectively from the driving wheel, two the equal fixedly connected with second transmission piece of inner wall from the driving wheel, the one end of second transmission piece extends to the inner chamber of second transmission groove, the side of metal drive belt is laminated with the medial surface of action wheel and follow driving wheel respectively mutually.

Optionally, the inner cavity of the raw material conveying box is rotatably connected with a second spiral conveying rod, the inner wall of the raw material conveying box is provided with a heating ring, the top of the raw material conveying box is provided with a charging barrel, the inner cavity of the charging barrel is rotationally connected with a first spiral conveying rod, the side surface of the first spiral conveying rod is fixedly connected with a scraping plate, the side surface of the scraping plate is attached to the inner wall of the charging barrel, the top end of the rotating shaft of the first spiral material conveying rod extends to the top of the material discharging barrel and is fixedly sleeved with a helical gear, the top of the charging barrel is provided with a support frame, the top of the support frame is rotatably connected with a transmission shaft, the middle part of the transmission shaft is fixedly sleeved with another bevel gear, the two bevel gears are mutually meshed, the one end of transmission shaft extends to one side of support frame and fixed the cup joint has first belt pulley, the other end of transmission shaft extends to the opposite side of support frame and fixed cup joint has the second belt pulley.

Optionally, the bottom of base is provided with the water storage box, the side fixedly connected with of water storage box absorbs water the pipe, the one end that absorbs water the pipe extends to the inner chamber of water storage box, the middle part that absorbs water the pipe is provided with the second check valve.

Optionally, the pressurization shaping groove has been seted up to the inside of pressurization shaping case, the one end in pressurization shaping groove is linked together with the inner chamber of raw materials transfer case, the cooling bath has been seted up to the inside of pressurization shaping case, the top fixedly connected with back flow of pressurization shaping case, the one end of back flow extends to the inner chamber of cooling bath, the other end of back flow extends to the inner chamber of water storage box, the top fixedly connected with aqueduct of pressurization shaping case, the one end of aqueduct extends to the inner chamber of cooling bath, the other end of aqueduct extends to the inner chamber of suction box, the middle part of aqueduct is provided with a check valve.

Optionally, one end of the driving shaft extends to the outside of the cutting box and is fixedly sleeved with another second belt pulley, and the second belt pulleys are in transmission connection through a second transmission belt.

Optionally, the fixed cover of one end of driving shaft has connect the carousel, the side of carousel rotates and is connected with the connecting rod, the one end of connecting rod rotates and is connected with the lift post, the one end movable sleeve of lift post connects to the inner chamber and the fixedly connected with piston of suction box, the side of piston is laminated with the inner wall of suction box mutually.

Optionally, the one end of first bidirectional screw rod extends to the outside of cut-off box and fixed the cup joint has a straight-teeth gear, the one end of first bidirectional screw rod is provided with the knob, the one end of second bidirectional screw rod extends to the outside of cut-off box and fixed the cup joint has another straight-teeth gear, two the straight-teeth gear passes through gear belt transmission and connects.

Optionally, a servo motor is fixedly mounted at the top of the base, one end of an output shaft of the servo motor is fixedly connected with a rotating shaft of the second spiral conveying rod, another first belt pulley is fixedly sleeved on the side face of the output shaft of the servo motor, and the two first belt pulleys are in transmission connection through a first transmission belt.

Optionally, the front of the charging barrel is hinged with a sealing door, and the front of the charging barrel is provided with a transparent window.

Optionally, the side of the first transmission block is attached to the inner wall of the first transmission groove, and the side of the second transmission block is attached to the inner wall of the second transmission groove.

The invention provides a compression molding device for carbon production, which has the following beneficial effects:

1. this pressurization forming device is used in carbon production, when the driving shaft rotates, the transmission through first transmission groove and first transmission piece drives the action wheel and follows the driving shaft and rotate, in addition through the action wheel, metal transmission belt and from the transmission drive between the driving wheel rotate, it is rotatory to drive the driven shaft through the transmission between second transmission groove and the second transmission piece, it is rotatory to utilize the driven shaft to drive the cam, make through the rotatory extrusion pressing post of cam and press post and cut off the sword downstream, promote the cut off sword and press the post rebound through the spring simultaneously, the function of cutting off has been realized carrying out to the carbon rod after the pressure forming.

2. The pressure forming device for carbon production is used by matching a first bidirectional screw rod, a second bidirectional screw rod, a driving shaft, a driven shaft, a straight gear, a gear belt, a knob, a first movable block, a driving wheel, a metal transmission belt, a second movable block and a driven wheel, when the cutting length of a carbon rod needs to be adjusted, the knob is rotated to drive the first bidirectional screw rod to rotate, the second bidirectional screw rod is driven to synchronously rotate by the transmission of the straight gear and the gear belt, the moving directions of the driving wheel and the driven wheel are always opposite by the opposite thread directions of the first bidirectional screw rod and the second bidirectional screw rod, the transmission position of the metal transmission belt is changed by changing the distance between the two driving wheels and the two driven wheels, so that the rotating speed ratio between the driving wheel and the driven wheel is changed, the rotating speed of the driven shaft and a cam is further changed, and the vertical reciprocating speed of a cutting knife and a pressing column is further adjusted, the function of adjusting the cutting length of the carbon rod is realized.

3. This pressurization forming device is used in carbon production, it is rotatory to drive the carousel through the driving shaft, the rotation that utilizes the carousel drives the reciprocal pulling lift post of connecting rod and rises and descends, make the inner chamber of water storage box inner chamber from the suction pipe suction to the suction box, and send water into the inner chamber of cooling bath from the inner chamber of suction box through the aqueduct, cool down the carbon-point that is located pressurization shaping inslot inner chamber through water and accelerate its solidification rate, the automatic inner chamber of taking into the cooling bath to the cooling water of water storage box inner chamber carries out the function of cooling to extrusion's carbon-point.

Drawings

FIG. 1 is a schematic cross-sectional view of the present invention;

FIG. 2 is a schematic structural diagram of the front side of the present invention;

FIG. 3 is a schematic cross-sectional view of the shear box of the present invention;

FIG. 4 is a schematic view of the interior of the disconnect box of the present invention;

FIG. 5 is a schematic cross-sectional view of the capstan of the present invention;

figure 6 is a schematic cross-sectional view of the pumping tank of the present invention;

FIG. 7 is an enlarged schematic view of the invention at A in FIG. 3;

FIG. 8 is an enlarged view of the point B in FIG. 3;

fig. 9 is an enlarged schematic view of the invention at C in fig. 3.

In the figure: 1. a base; 2. a raw material delivery box; 3. pressurizing and forming a box; 4. placing a material barrel; 5. a first screw conveying rod; 6. a second screw conveying rod; 7. heating a ring; 8. a support frame; 9. a cutting box; 10. a transport mechanism; 11. a drive shaft; 12. a helical gear; 13. a first pulley; 14. a servo motor; 15. a first drive belt; 16. a squeegee; 17. a second pulley; 18. a second belt; 19. a water storage tank; 20. a water pumping box; 21. a speed regulating chamber; 22. a first bidirectional screw; 23. a second bidirectional screw rod; 24. a drive shaft; 25. a driven shaft; 26. a spur gear; 27. a gear belt; 28. a knob; 29. a contraction chamber; 30. a cam; 31. a spring; 32. pressing the column; 33. a ball bearing; 34. a cutting knife; 35. a first movable block; 36. a driving wheel; 37. a first transmission groove; 38. a first transmission block; 39. a metal transmission belt; 40. a second movable block; 41. a driven wheel; 42. a second transmission groove; 43. a second transmission block; 44. pressurizing and forming the groove; 45. a cooling tank; 46. a return pipe; 47. a turntable; 48. a connecting rod; 49. a lifting column; 50. a piston; 51. a water conduit; 52. a first check valve; 53. a suction pipe; 54. a second one-way valve; 55. a sealing door; 56. a transparent window.

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.

Referring to fig. 1 to 9, the present invention provides a technical solution: a pressure forming device for carbon production comprises a base 1, a first transmission belt 15, a second transmission belt 18, a gear belt 27 and a metal transmission belt 39, wherein a raw material conveying box 2 is arranged at the top of the base 1, a pressure forming box 3 is fixedly connected to the side surface of the raw material conveying box 2, a conveying mechanism 10 is arranged at one end, located on the top surface of the base 1, of the pressure forming box 3, a cutting box 9 is arranged on the top surface of the base 1 and located above the conveying mechanism 10, a water pumping box 20 is arranged on the side surface of the cutting box 9, a speed regulating chamber 21 is arranged inside the cutting box 9, a contraction chamber 29 is arranged inside the cutting box 9, a spring 31 is fixedly connected to the bottom of an inner cavity of the contraction chamber 29, a pressing column 32 is fixedly connected to the top end of the spring 31, a cutting knife 34 is fixedly connected to the bottom surface of the pressing column 32, one end of the cutting knife 34 extends to the bottom of the cutting box 9, a movable sleeve at the top end of the pressing column 32 is connected to the inner cavity of the speed regulating chamber 21 and is clamped with a ball 33, the inner cavity of the speed regulation chamber 21 is rotatably connected with a driven shaft 25, the surface of the driven shaft 25 is provided with a second transmission groove 42, the surface of the driven shaft 25 is fixedly sleeved with a cam 30, the side surface of the cam 30 is contacted with the surface of a ball 33, the inner cavity of the speed regulation chamber 21 is rotatably connected with a first bidirectional screw 22, the inner cavity of the speed regulation chamber 21 is rotatably connected with a second bidirectional screw 23, the first bidirectional screw 22 and the second bidirectional screw 23 have the same parameters such as thread pitch and diameter, but the thread directions are opposite, so that when the first bidirectional screw 22 drives two first movable blocks 35 to move inwards, the second bidirectional screw 23 drives two second movable blocks 40 to move outwards, and vice versa, the inner cavity of the speed regulation chamber 21 is rotatably connected with a driving shaft 24, the surface of the driving shaft 24 is provided with a first transmission groove 37, two ends of the first bidirectional screw 22 are respectively in threaded sleeve connection with the first movable blocks 35, and the two first movable blocks 35 are respectively in movable sleeve connection with the driving shaft 24, the first movable blocks 35 are limited by the driving shaft 24, so that the first movable blocks 35 can only move along the axial direction of the first bidirectional screw 22, the inner sides of the two first movable blocks 35 are respectively and rotatably connected with driving wheels 36, the two driving wheels 36 are respectively and movably sleeved with the driving shaft 24, the inner walls of the two driving wheels 36 are respectively and fixedly connected with first transmission blocks 38, one ends of the first transmission blocks 38 extend to the inner cavity of the first transmission grooves 37, the two ends of the second bidirectional screw 23 are respectively and threadedly sleeved with second movable blocks 40, the two second movable blocks 40 are respectively and movably sleeved with the driven shaft 25, the second movable blocks 40 are limited by the driven shaft 25, so that the second movable blocks 40 can only move along the axial direction of the second bidirectional screw 23, the inner sides of the two second movable blocks 40 are respectively and rotatably connected with driven wheels 41, and the two driven wheels 41 are respectively and movably sleeved with the driven shaft 25, the inner walls of the two driven wheels 41 are fixedly connected with second transmission blocks 43, one ends of the second transmission blocks 43 extend to the inner cavity of the second transmission groove 42, and the side surfaces of the metal transmission belts 39 are respectively attached to the inner side surfaces of the driving wheel 36 and the driven wheels 41.

Wherein, the inner cavity of the raw material conveying box 2 is rotatably connected with a second spiral conveying rod 6, the carbon production raw material is driven to move forwards by the rotation of the second spiral conveying rod 6 and is preliminarily pressurized, the inner wall of the raw material conveying box 2 is provided with a heating ring 7, the carbon raw material is heated by the heating ring 7 so as to be conveniently pressurized and molded, the top of the raw material conveying box 2 is provided with a material discharging barrel 4, the inner cavity of the material discharging barrel 4 is rotatably connected with a first spiral conveying rod 5, the side surface of the first spiral conveying rod 5 is fixedly connected with a scraper 16, the side surface of the scraper 16 is attached to the inner wall of the material discharging barrel 4, the carbon production raw material attached to the inner wall of the material discharging barrel 4 is scraped off by the scraper 16, the top end of the rotating shaft of the first spiral conveying rod 5 extends to the top of the material discharging barrel 4 and is fixedly sleeved with a helical gear 12, the top of the material discharging barrel 4 is provided with a support 8, the top of the support 8 is rotatably connected with a transmission shaft 11, another helical gear 12 is fixedly sleeved in the middle of the transmission shaft 11, the two helical gears 12 are meshed with each other, one end of the transmission shaft 11 extends to one side of the support frame 8 and is fixedly sleeved with a first belt pulley 13, and the other end of the transmission shaft 11 extends to the other side of the support frame 8 and is fixedly sleeved with a second belt pulley 17.

The water storage tank 19 is arranged at the bottom of the base 1, the water suction pipe 53 is fixedly connected to the side face of the water storage tank 19, one end of the water suction pipe 53 extends to the inner cavity of the water pumping tank 20, the second one-way valve 54 is arranged in the middle of the water suction pipe 53, and the second one-way valve 54 only allows water in the inner cavity of the water storage tank 19 to enter the inner cavity of the water pumping tank 20 from the water suction pipe 53.

Wherein, the inside of the pressure forming box 3 is provided with a pressure forming groove 44, one end of the pressure forming groove 44 is communicated with the inner cavity of the raw material conveying box 2, the bottom surface of the other end of the pressure forming groove 44 is level with the top surface of the conveying mechanism 10, so as to ensure that the columnar carbon rod coming out from the pressure forming groove 44 smoothly enters the surface of the conveying mechanism 10, the inside of the pressure forming box 3 is provided with a cooling groove 45, the top of the pressure forming box 3 is fixedly connected with a return pipe 46, one end of the return pipe 46 extends to the inner cavity of the cooling groove 45, the other end of the return pipe 46 extends to the inner cavity of the water storage box 19, the top of the pressure forming box 3 is fixedly connected with a water guide pipe 51, one end of the water guide pipe 51 extends to the inner cavity of the cooling groove 45, the other end of the water guide pipe 51 extends to the inner cavity of the water pumping box 20, the middle part of the water guide pipe 51 is provided with a first one-way valve 52, and the first one-way valve 52 can only allow water in the inner cavity of the water pumping box 20 to enter the inner cavity of the cooling groove 45 through the water guide pipe 51.

Wherein, one end of driving shaft 24 extends to the outside of cutting-off box 9 and the fixed cover is connected with another second belt pulley 17, and two second belt pulleys 17 pass through second drive belt 18 transmission connection.

Wherein, the fixed cover of one end of driving shaft 24 is connected with carousel 47, and the side of carousel 47 rotates and is connected with connecting rod 48, and the one end of connecting rod 48 rotates and is connected with lift post 49, and the one end activity cover of lift post 49 connects to the inner chamber of suction box 20 and fixedly connected with piston 50, and lift post 49 can only carry out the motion of vertical direction, and the side of piston 50 is laminated with the inner wall of suction box 20 mutually.

Wherein, one end of the first bidirectional screw rod 22 extends to the outside of the cutting box 9 and is fixedly sleeved with a spur gear 26, one end of the first bidirectional screw rod 22 is provided with a knob 28, one end of the second bidirectional screw rod 23 extends to the outside of the cutting box 9 and is fixedly sleeved with another spur gear 26, the two spur gears 26 are in transmission connection through a gear belt 27, the second bidirectional screw rod 23 is driven to synchronously rotate when the knob 28 rotates the first bidirectional screw rod 22, and therefore the distance between the two driving wheels 36 and the two driven wheels 41 is adjusted.

Wherein, the top fixed mounting of base 1 has servo motor 14, and the one end of servo motor 14 output shaft and the pivot fixed connection of second spiral material conveying pole 6, the side of servo motor 14 output shaft is fixed to be cup jointed another first belt pulley 13, and two first belt pulleys 13 are connected through the transmission of first drive belt 15.

Wherein, the front of blowing section of thick bamboo 4 articulates there is sealing door 55, opens sealing door 55 and adds carbon raw materials for production to the inner chamber of blowing section of thick bamboo 4, and the front of blowing section of thick bamboo 4 is provided with transparent window 56.

Wherein, the side of first drive block 38 is laminated with the inner wall of first drive groove 37 mutually, cooperation through first drive block 38 and first drive groove 37 is connected between driving shaft 24 and the action wheel 36, it is rotatory to make driving shaft 24 drive action wheel 36 when rotating, the side of second drive block 43 is laminated with the inner wall of second drive groove 42 mutually, cooperation through second drive block 43 and second drive groove 42 is connected between driven shaft 25 and the follow driving wheel 41, it is rotatory to make driven shaft 25 drive the follow driving wheel 41 when rotating.

In conclusion, when the pressure forming device for carbon production is used, the sealing door 55 is opened to place the raw material for carbon production into the inner cavity of the charging barrel 4, the servo motor 14 and the heating ring 7 are started, the rotation of the output shaft of the servo motor 14 drives the second spiral conveying rod 6 to rotate, the transmission shaft 11 is driven to rotate through the transmission of the first belt pulley 13 and the first transmission belt 15, the first spiral conveying rod 5 and the scraper 16 are driven to rotate through the meshing transmission of the two bevel gears 12, so that the raw material for carbon production in the inner cavity of the charging barrel 4 is guided into the inner cavity of the raw material conveying box 2, the raw material for carbon production in the inner cavity of the raw material conveying box 2 moves forward under the action of the second spiral conveying rod 6, the raw material for carbon production is heated through the heating ring 7, the raw material for carbon production with heat enters the inner cavity of the pressure forming groove 44, the raw material for carbon production is pressed into the columnar carbon rod in the inner cavity of the pressure forming groove 44, in addition, the driving shaft 24 is driven to rotate by the transmission of the second belt pulley 17 and the second transmission belt 18, the driving shaft 24 drives the rotating disc 47 to rotate, the rotating disc 47 is driven to drive the connecting rod 48 to pull the lifting column 49 to ascend and descend in a reciprocating way by the rotation of the rotating disc 47, so that the water in the inner cavity of the water storage tank 19 is pumped into the inner cavity of the water pumping tank 20 from the water suction pipe 53, the water is sent into the inner cavity of the cooling tank 45 from the inner cavity of the water pumping tank 20 through the water guide pipe 51, the carbon rod in the inner cavity of the pressure forming tank 44 is cooled by the water to accelerate the solidification speed, the water at the bottom of the inner cavity of the cooling tank 45 flows back to the inner cavity of the water storage tank 19 from the return pipe 46, the driving wheel 36 is driven by the rotation of the driving shaft 24, the driven shaft 25 is driven to rotate by the transmission among the driving wheel 36, the metal transmission belt 39 and the driven wheel 41, the cam 30 is driven by the driven shaft 25, so that the cam 30 repeatedly pushes the pressing column 32 and the cutting knife 34 to move downwards, when the carbon rod from the pressure forming groove 44 enters the conveying mechanism 10, the carbon rod is cut by the cutting knife 34, when the cutting length of the carbon rod needs to be adjusted, namely, the time required by the vertical reciprocating motion of the cutting knife 34 is adjusted, the first bidirectional screw 22 is driven to rotate by the rotating knob 28, the second bidirectional screw 23 is driven to synchronously rotate by the transmission of the spur gear 26 and the gear belt 27, when the two first movable blocks 35 and the driving wheel 36 are driven to move inwards by the rotation of the first bidirectional screw 22, the second bidirectional screw 23 drives the two second movable blocks 40 and the driven wheel 41 to move outwards, so that the rotating speeds of the driven shaft 25 and the cam 30 are increased, the cutting speed of the cutting knife 34 is increased, the cutting length of the carbon rod is shortened, when the two first movable blocks 35 and the driving wheel 36 are driven to move outwards by the rotation of the first bidirectional screw 22, the second bidirectional screw 23 drives the two second movable blocks 40 and the driven wheel 41 to move inwards, so that the rotating speed of the driven shaft 25 and the cam 30 is reduced, the cutting speed of the cutting knife 34 is reduced, and the cutting length of the carbon rod is increased.

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 the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.