CN117382981A - Cable type steel wire coil core ring conveying device - Google Patents

Abstract

The invention relates to the field of core ring processing, in particular to a cable steel wire ring core ring conveying device. Comprising the following steps: screening a feeding disc; the transfer conveying mechanism comprises a bearing top plate, a bearing chassis, a counting transfer mechanism, a first motor, a containing disc, a plurality of iron containing frames, two first blanking pipes, two second blanking pipes and two anti-drop mechanisms, wherein the bearing chassis is coaxially arranged below the bearing top plate, the two first blanking pipes are arranged at the lower end of the bearing top plate and are respectively connected with the two first blanking pipes, the two second blanking pipes are respectively fixedly connected with the bearing chassis, the counting transfer mechanism is connected with the bearing chassis, the two anti-drop mechanisms are respectively connected with the two first blanking pipes, the containing disc is arranged at the side below the bearing chassis, the iron containing frames are connected with the upper end of the containing disc, the first motor is arranged at the lower end of the containing disc, and the output end of the first motor is fixedly connected with the containing disc. The reciprocating pressing mechanism can push the core ring to move in the first blanking pipe.

Description

Cable type steel wire coil core ring conveying device

Technical Field

The invention relates to the field of core ring processing, in particular to a cable steel wire ring core ring conveying device.

Background

Typically, the coils of the cable-type steel coil are transported in batches and packaged during transport. Since the core rings are often an important component for assembling the wire rope, the core rings are mass-produced during the production process and are packaged and transported in batches according to certain specifications and dimensions.

The batch transportation can improve the transportation efficiency and reduce the transportation cost. Multiple coils may be packaged or loaded together in a shipping container, such as a wooden case, pallet or container, for centralized management and shipping. This also reduces the risk of damage and loss during transport.

But when carrying out the bulk transportation, the workman still needs to carry out the group's partial shipment to the core circle, because of the core circle diameter is too little this moment, can be very big consume workman's energy through the manual split charging, be unfavorable for the high-efficient transport of core circle, this is done all can to this, most mill adopts automated machinery partial shipment, but because core circle self shape is limited this moment, the ring appearance of core circle can receive the extrusion force to take place the drunkenness at the core circle, the mill needs to carry out further spacing to the core circle this moment, this process very big improvement the complexity of device, and the core circle of different specifications needs operating personnel to carry out different transformation to stop gear, and then improved processing cost.

In this regard, it is understood that the particular manner of delivery and packaging may vary from one production to another and from one transportation requirement to another. Therefore, in the case of actual work, batch transport and packaging are performed according to actual requirements to ensure that the core ring can be transported to the destination safely and efficiently.

Disclosure of Invention

Based on the above, it is necessary to provide a cable-type bead ring conveying device for solving the problems of the prior art.

In order to solve the problems in the prior art, the invention adopts the following technical scheme:

cable type steel wire coil core circle conveyor includes:

screening a feeding disc;

the transfer conveying mechanism is arranged at the side of the screening feeding disc and comprises a U-shaped groove, a supporting top disc, a supporting chassis, a counting and transferring mechanism, a first motor, a containing disc, a plurality of containing iron frames, two first blanking tubes, two second blanking tubes and two anti-drop mechanisms, wherein the U-shaped groove is fixedly connected with the output end of the screening feeding disc, the supporting top disc is rotationally connected with the lower end of the U-shaped groove, the supporting chassis is coaxially arranged below the supporting top disc, the two first blanking tubes are symmetrically arranged at the lower end of the supporting top disc, the two second blanking tubes are respectively connected with the two first blanking tubes in a coaxial sliding mode, the two second blanking tubes are respectively fixedly connected with the supporting chassis, the counting and transferring mechanism is connected with the supporting chassis, the two anti-drop mechanisms are respectively connected with the two first blanking tubes, the containing disc is arranged at the side of the lower part of the supporting chassis, the plurality of containing iron frames are arranged along the circumferential direction of the upper end of the containing disc at the same angle, the first motor is arranged at the lower end of the containing disc, and the output end of the first motor is fixedly connected with the containing disc.

The reciprocating pressing mechanism is arranged above the supporting top disc and can push the core ring to move in the first blanking pipe.

Further, the bearing top plate is provided with two blanking through holes in a forming mode, the first blanking pipe is provided with an avoidance perforation, the bearing chassis is provided with a blanking perforation in a forming mode, the transfer conveying mechanism further comprises a limiting bearing ring, two bearing pipe covers and two bearing balls, the limiting bearing ring is connected with the lower end of the bearing chassis in a coaxial line rotating mode, the two first blanking pipes are respectively connected with the two blanking through holes in a coaxial line mode, the two second blanking pipes are respectively connected with the two blanking perforation in a coaxial line mode, the middle portions of the two bearing pipe covers are respectively hinged with the two second blanking pipes through torsion springs, the two bearing pipe covers are respectively provided with limiting portions in a forming mode, the two bearing balls are respectively connected with the two limiting portions in a rotating mode, limiting grooves are formed in the limiting bearing ring in a forming mode along the circumferential direction, and the two bearing balls can respectively abut against the limiting grooves in the rotating process of the bearing top plate.

Further, the transfer conveying mechanism further comprises a driving sleeve shaft, a reset spring, a driving main shaft, a power gear, a power residual tooth, a driving belt wheel and a driven belt wheel, wherein the driving sleeve shaft is fixedly connected with the supporting top disc in a coaxial line, the upper end of the driving main shaft is connected with the driving sleeve shaft in a key manner, the driving belt wheel is fixedly connected with the output end of the first motor in a coaxial line, the driven belt wheel is rotatably arranged at the side of the first motor and is in transmission connection with the driving belt wheel through a belt, the power residual tooth is fixedly connected with the lower end of the driven belt wheel in a coaxial line, the power gear is rotatably arranged at the side of the power residual tooth, the power gear is meshed with the power residual tooth, the lower end of the driving main shaft is fixedly connected with the power gear in a coaxial line, one end of the reset spring is coaxially sleeved outside the driving main shaft and is abutted against the power gear, and the other end of the reset spring is abutted against the driving sleeve shaft.

Further, count transfer mechanism is including pushing down branch, spacing snap ring, pushing down the rack, pushing down gear and reversing gear, pushing down branch and spacing carrier ring link firmly, spacing snap ring and pushing down the lower extreme of branch link firmly, spacing snap ring and drive sleeve rotation are connected, push down the rack and push down the branch and keep away from one side fixed connection of spacing snap ring, push down the gear rotation setting and push down the rack and mesh with pushing down the rack in the side of pushing down the rack, reversing gear sets up and keeps away from the one side of pushing down the rack at pushing down the gear, reversing gear meshes with pushing down the gear.

Further, count transfer mechanism still includes first band pulley, second band pulley, first bevel gear, second bevel gear, transfer gear and drive ring gear, first band pulley links firmly with the switching-over gear coaxial line, the second band pulley sets up in the top of first band pulley and links to each other with first band pulley transmission through the belt, first bevel gear links firmly with the second band pulley coaxial line, the second bevel gear meshes with first bevel gear mutually, transfer gear links firmly with second bevel gear coaxial line, the drive ring gear rotates with the lower extreme coaxial line of bearing footwall and is connected, drive ring gear meshes with transfer gear mutually.

Further, the anti-drop mechanism further comprises two first gears, two ratchet wheels, two second gears, two driving racks and two stop baffles, wherein the two first gears are rotationally arranged in the driving gear ring, the two first gears are respectively meshed with the inner side of the driving gear ring, one sides of the two ratchet wheels are respectively and coaxially fixedly connected with the two first gears, the two second gears are respectively fixedly connected with the other sides of the two ratchet wheels, the two driving gears are respectively meshed with the two second gears, the two driving racks are respectively and slidably arranged at the sides of the two driving gears, the two driving racks are respectively meshed with the two driving gears, the two stop baffles are respectively fixedly connected with one ends of the two driving racks, which are close to the first blanking pipe, and the two stop baffles are respectively and fixedly connected with the avoiding perforation sliding.

Further, the reciprocating pressing mechanism further comprises a pressing fork rod, the pressing fork rod is arranged above the U-shaped groove in a vertical state, the pressing fork rod is in sliding connection with the supporting curved seat through the rod seat, and the lower end of the pressing fork rod can be propped against the core ring in the first blanking pipe.

Further, the reciprocating pressing mechanism further comprises a limiting disc, a sliding short pin, a deflection disc, an adjusting slide block and an adjusting support, wherein the deflection disc is fixedly connected with the output end of the second motor, the adjusting support is fixedly connected with one side, far away from the second motor, of the deflection disc, the adjusting slide block is in sliding connection with the adjusting support, the middle part of the adjusting screw is in threaded connection with the adjusting slide block, two ends of the adjusting screw are respectively in rotating connection with the adjusting support, the limiting disc is fixedly connected with the adjusting slide block, one end of the sliding short pin is in sliding connection with an annular groove on the surface of the limiting disc, and the other end of the sliding short pin is hinged with the upper end of the pressing fork rod.

Compared with the prior art, the invention has the following beneficial effects:

the method comprises the following steps: the device can carry out grouping and storage on the core rings through the matching of the first blanking pipe and the second blanking pipe, is convenient for the automatic statistics of the core rings in the conveying process, does not need operators to count and group one by one, and improves the processing efficiency;

and two,: compared with the traditional grouping counting mechanism which can not accurately store the annular core rings, the device automatically counts each group of core rings through the automatic pressing down of the core rings, and an air cylinder and an infrared detector are not needed, so that the structure of the device is simplified;

and thirdly,: this device can detect the core circle of different specifications, and the transportation of accomodating of the different core circles of adaptation of being convenient for, at this in-process, operating personnel can be through rotating adjusting screw and come to push down the moving distance of fork arm and carry out the preconditioning, prevent to push down the fork arm and can't promote whole core circle of group and carry out the displacement.

Drawings

FIG. 1 is a schematic perspective view of an embodiment;

FIG. 2 is a side view of a perspective structure of an embodiment;

FIG. 3 is an enlarged view of the structure of FIG. 2 at A;

FIG. 4 is an enlarged view of the structure at B in FIG. 2;

FIG. 5 is an enlarged view of the structure at C in FIG. 2;

FIG. 6 is an exploded view of the perspective of the reciprocating hold down mechanism in an embodiment;

FIG. 7 is an enlarged view of the structure at D in FIG. 6;

FIG. 8 is an enlarged view of the structure at E in FIG. 6;

fig. 9 is a perspective cut-away view of the transfer conveyor in an embodiment.

The reference numerals in the figures are:

1. screening a feeding disc; 2. a transfer transport mechanism; 3. a U-shaped groove; 4. a supporting top plate; 5. a blanking through hole; 6. a first blanking pipe; 7. avoiding perforation; 8. a supporting chassis; 9. blanking and perforating; 10. a second blanking pipe; 11. a carrier tube cap; 12. a limit part; 13. bearing balls; 14. a limit bearing ring; 15. limiting grooves; 16. a counting transfer mechanism; 17. pressing down the support rod; 18. a limiting snap ring; 19. pressing down the rack; 20. pressing down the gear; 21. a reversing gear; 22. a first pulley; 23. a second pulley; 24. a first bevel gear; 25. a second bevel gear; 26. a transfer gear; 27. driving the gear ring; 28. an anti-drop mechanism; 29. a first gear; 30. a ratchet wheel; 31. a second gear; 32. a drive gear; 33. a drive rack; 34. a stop baffle; 35. a return spring; 36. driving the sleeve shaft; 37. driving a main shaft; 38. a power gear; 39. power tooth residue; 40. a driving pulley; 41. a driven pulley; 42. a first motor; 43. a receiving disc; 44. an iron frame is accommodated; 45. a reciprocating pressing mechanism; 46. pressing down the fork rod; 47. a limit disc; 49. a sliding short pin; 50. a deflection disc; 51. adjusting a screw; 52. an adjusting slide block; 53. adjusting the support; 54. a second motor; 55. and (5) supporting the curved seat.

Detailed Description

The invention will be further described in detail with reference to the drawings and the detailed description below, in order to further understand the features and technical means of the invention and the specific objects and functions achieved.

With reference to figures 1 to 9 of the drawings,

cable type steel wire coil core circle conveyor includes:

screening a feeding disc 1;

the transfer conveying mechanism 2 is arranged at the side of the screening feeding disc 1 and comprises a U-shaped groove 3, a supporting top disc 4, a supporting chassis 8, a counting transfer mechanism 16, a first motor 42, a containing disc 43, a plurality of containing iron frames 44, two first blanking pipes 6, two second blanking pipes 10 and two anti-disengaging mechanisms 28, the U-shaped groove 3 is fixedly connected with the output end of the screening feeding disc 1, the supporting top disc 4 is rotationally connected with the lower end of the U-shaped groove 3, the supporting chassis 8 is coaxially arranged below the supporting top disc 4, the two first blanking pipes 6 are symmetrically arranged at the lower end of the supporting top disc 4, the two second blanking pipes 10 are respectively connected with the two first blanking pipes 6 in a sliding mode, the two second blanking pipes 10 are respectively fixedly connected with the supporting chassis 8, the counting transfer mechanism 16 is connected with the supporting chassis 8, the two anti-disengaging mechanisms 28 are respectively connected with the two first blanking pipes 6, the containing disc 43 is arranged at the side of the lower part of the supporting chassis 8, the plurality of containing iron frames 44 are arranged at equal angles along the circumferential direction of the upper end of the containing disc 43, the first motor 42 is arranged at the lower end of the first motor 42, and the first motor is fixedly connected with the lower end of the first disc 43.

The reciprocating pushing mechanism 45 is arranged above the supporting top disc 4 and can push the core ring to move in the first blanking pipe 6. When the device operates, the screening feeding disc 1 is started to sequentially push a plurality of core rings into the U-shaped groove 3, then the reciprocating pushing mechanism 45 is started to push the core rings in the first blanking pipe 6 at the lower end of the U-shaped groove 3 downwards, the core rings can be sequentially stacked downwards in the process, and an operator can adjust the reciprocating pushing mechanism 45 at the moment so as to control the stacking height of the core rings and further control the quantity of the core rings conveyed every time.

When the coils are gradually stacked, along with the start of the reciprocating pushing mechanism 45, the reciprocating pushing mechanism 45 pushes the supporting chassis 8 and the supporting top tray 4 to perform relative displacement, the distance between the first blanking pipe 6 and the second blanking pipe 10 can be changed, and the counting and transferring mechanism 16 can drive a separation preventing mechanism 28 to seal the first blanking pipe 6 at the lower end of the U-shaped groove 3, so that a group of coils are conveyed. Then, the first motor 42 is started and drives the accommodating disc 43 to rotate, when the accommodating disc 43 rotates, the accommodating disc 43 finally drives the supporting top disc 4 to rotate until the first blanking pipe 6 containing the core rings moves to the side of the accommodating iron frame 44, when the first blanking pipe 6 moves to the side of the accommodating iron frame 44, the core rings fall onto the accommodating iron frame 44 under the action of gravity, and at the moment, the core rings are conveyed and accommodated in groups.

In order to avoid the core ring inside the second blanking pipe 10 from falling, the following features are specifically provided:

the bearing top plate 4 is provided with two blanking through holes 5, the first blanking pipe 6 is provided with an avoidance perforation 7, the bearing bottom plate 8 is provided with a blanking perforation 9, the transfer conveying mechanism 2 further comprises a limiting bearing ring 14, two bearing pipe covers 11 and two bearing balls 13, the limiting bearing ring 14 is coaxially and rotatably connected with the lower end of the bearing bottom plate 8, the two first blanking pipes 6 are respectively and fixedly connected with the two blanking through holes 5 in a coaxial way, the two second blanking pipes 10 are respectively and fixedly connected with the two blanking perforations 9 in a coaxial way, the middle parts of the two bearing pipe covers 11 are respectively hinged with the two second blanking pipes 10 through torsion springs, the two bearing balls 13 are respectively and rotatably connected with the two limiting parts 12, the limiting bearing ring 14 is provided with limiting grooves 15 in a forming mode along the circumferential direction, and the two bearing balls 13 can respectively abut against the limiting grooves 15 in the rotating process of the bearing top plate 4. When the positions of the two second blanking pipes 10 are interchanged, the two bearing balls 13 can move along the limiting groove 15, and at the moment, when the bearing pipe cover 11 is positioned beside the limiting groove 15, the bearing pipe cover 11 can deflect along the hinge point to open the lower end of the second blanking pipe 10, so that the core ring inside the second blanking pipe 10 can fall into the iron storage frame 44. Similarly, when the second discharging tube 10 is located at the lower end of the U-shaped groove 3, the carrying tube cover 11 is closed with the lower end of the second discharging tube 10, so as to prevent the core ring inside the second discharging tube 10 from falling. In the initial stage of slow opening of the carrier tube cover 11 during the movement of the carrier tube cover 11 along the limiting carrier ring 14, the gap between the carrier tube cover 11 and the second blanking tube 10 is too small, so that the core ring in the second blanking tube 10 does not drop, and further the core ring is prevented from being blanked in advance.

In order to prevent the first blanking pipe 6 and the second blanking pipe 10 from being relatively displaced, the following features are specifically provided:

the transfer conveying mechanism 2 further comprises a driving sleeve shaft 36, a reset spring 35, a driving main shaft 37, a power gear 38, a power residual tooth 39, a driving pulley 40 and a driven pulley 41, wherein the driving sleeve shaft 36 is fixedly connected with the supporting top disc 4 in a coaxial line, the upper end of the driving main shaft 37 is connected with the driving sleeve shaft 36 in a key manner, the driving pulley 40 is fixedly connected with the output end of the first motor 42 in a coaxial line, the driven pulley 41 is rotatably arranged at the side of the first motor 42 and is in transmission connection with the driving pulley 40 through a belt, the power residual tooth 39 is fixedly connected with the lower end of the driven pulley 41 in a coaxial line, the power gear 38 is rotatably arranged at the side of the power residual tooth 39, the power gear 38 is meshed with the power residual tooth 39, the lower end of the driving main shaft 37 is fixedly connected with the power gear 38 in a coaxial line, the reset spring 35 is coaxially sleeved outside the driving main shaft 37, one end of the reset spring 35 is abutted against the power gear 38, and the other end of the reset spring 35 is abutted against the driving sleeve shaft 36. After the first motor 42 is started, the first motor 42 drives the driven pulley 41 to rotate through the driving pulley 40, the driven pulley 41 drives the power gear 38 to rotate through the power residual teeth 39, the power gear 38 drives the driving sleeve shaft 36 to rotate through the driving main shaft 37, the driving sleeve shaft 36 drives the supporting top disc 4 to rotate, and along with the rotation of the supporting top disc 4, the supporting top disc 4 drives the supporting chassis 8 to rotate through the two first blanking pipes 6 and the two second blanking pipes 10, so that the position interchange of the two second blanking pipes 10 is realized. The reset spring 35 can be convenient for support chassis 8 and the reset of support top tray 4 later stage, prevents that first unloading pipe 6 and second unloading pipe 10 can't take place relative displacement.

In order to limit the limit bearing ring 14, the following features are specifically provided:

the counting and transferring mechanism 16 comprises a pressing support rod 17, a limiting snap ring 18, a pressing rack 19, a pressing gear 20 and a reversing gear 21, wherein the pressing support rod 17 is fixedly connected with the limiting bearing ring 14, the limiting snap ring 18 is fixedly connected with the lower end of the pressing support rod 17, the limiting snap ring 18 is rotationally connected with a driving sleeve shaft 36, the pressing rack 19 is fixedly connected with one side, far away from the limiting snap ring 18, of the pressing support rod 17, the pressing gear 20 is rotationally arranged beside the pressing rack 19 and meshed with the pressing rack 19, the reversing gear 21 is arranged on one side, far away from the pressing rack 19, of the pressing gear 20, and the reversing gear 21 is meshed with the pressing gear 20. After the bearing chassis 8 and the bearing top disc 4 are relatively displaced, the bearing chassis 8 can push the pressing support rod 17 downwards to move, the pressing support rod 17 can drive the pressing rack 19 to move through the limiting clamp ring 18, and the pressing rack 19 can drive the reversing gear 21 to rotate through the pressing gear 20. In the process, the pressing rack 19 is in interference sliding connection with the workbench through the bracket, and the pressing rack 19 can lift the limit bearing ring 14. Namely, the downward-pressing rack 19 sequentially passes through the limiting snap ring 18 and the downward-pressing support rod 17 and then reacts on the lower end of the limiting bearing ring 14, so that the limiting bearing ring 14 is limited, and the phenomenon that the limiting bearing ring 14 moves due to the rotation of the bearing chassis 8 and further the opening and closing of the bearing pipe cover 11 are affected is avoided.

In order to avoid that the core ring inside the second blanking pipe 10 is pushed in the opposite direction, the following features are provided in particular:

the counting transfer mechanism 16 further comprises a first belt pulley 22, a second belt pulley 23, a first bevel gear 24, a second bevel gear 25, a transfer gear 26 and a driving gear ring 27, wherein the first belt pulley 22 is fixedly connected with the reversing gear 21 coaxially, the second belt pulley 23 is arranged above the first belt pulley 22 and is connected with the first belt pulley 22 in a transmission manner through a belt, the first bevel gear 24 is fixedly connected with the second belt pulley 23 coaxially, the second bevel gear 25 is meshed with the first bevel gear 24, the transfer gear 26 is fixedly connected with the second bevel gear 25 coaxially, the driving gear ring 27 is connected with the lower end of the supporting top disc 4 coaxially in a rotating manner, and the driving gear ring 27 is meshed with the transfer gear 26. When the reversing gear 21 rotates, the reversing gear 21 drives the second belt pulley 23 to rotate through the first belt pulley 22, the second belt pulley 23 drives the second bevel gear 25 to rotate through the first bevel gear 24, and the second bevel gear 25 can finally seal a core ring in the second blanking pipe 10 through the driving gear ring 27, so that the core ring in the second blanking pipe 10 is prevented from being pushed reversely.

In order to avoid spontaneous movements of the two driving racks 33 during the movement of the supporting top plate 4, the following features are provided:

the anti-falling mechanism 28 further comprises two first gears 29, two ratchet wheels 30, two second gears 31, two driving gears 32, two driving racks 33 and two stop baffles 34, wherein the two first gears 29 are rotatably arranged in the driving gear ring 27, the two first gears 29 are respectively meshed with the inner sides of the driving gear ring 27, one sides of the two ratchet wheels 30 are respectively fixedly connected with the two first gears 29 in a coaxial line, the two second gears 31 are respectively fixedly connected with the other sides of the two ratchet wheels 30, the two driving gears 32 are respectively meshed with the two second gears 31, the two driving racks 33 are respectively arranged beside the two driving gears 32 in a sliding mode, the two driving racks 33 are respectively meshed with the two driving gears 32, the two stop baffles 34 are respectively fixedly connected with one ends, close to the first blanking pipe 6, of the two driving racks 33, and the two stop baffles 34 are respectively connected with the avoidance holes 7 in a sliding mode. When the driving gear ring 27 rotates, the driving gear ring 27 rotates to drive the first gear 29 meshed with the driving gear ring to rotate, the first gear 29 drives the driving gear 32 to rotate through the ratchet 30 and the second gear 31, the driving gear 32 drives the stop baffle 34 to move through the driving rack 33, and the stop baffle 34 can stretch into the avoidance perforation 7 to stop the core ring in the first blanking pipe 6 after moving, so that the core ring is prevented from falling upwards under the action of the elastic force of the reset spring 35. It should be noted that the moving directions of the two driving racks 33 are opposite, so that the driving racks 33 can be reset when the first blanking pipe 6 moves to the upper end of the accommodating iron frame 44. The ratchet 30 ensures that the two driving racks 33 will move only when the driving gear ring 27 rotates, avoiding spontaneous movement of the two driving racks 33 during movement of the holding top plate 4.

In order to prevent the stopper plate 34 from colliding with the reciprocating depressing mechanism 45 when the stopper plate 34 blocks the core ring, the following features are provided in particular:

the reciprocating pressing mechanism 45 further comprises a pressing fork rod 46, the pressing fork rod 46 is arranged above the U-shaped groove 3 in a vertical state, the pressing fork rod 46 is in sliding connection with the supporting curved seat 55 through a rod seat, and the lower end of the pressing fork rod 46 can be propped against a core ring inside the first blanking pipe 6. When the core is pushed down, the end of the push-down fork 46 contacting the core can facilitate the two stop baffles 34 to pass through (referring to fig. 7, the bottom of the push-down fork 46 is inverted U-shaped), so as to prevent the stop baffles 34 from colliding with the reciprocating pushing mechanism 45 when the stop baffles 34 block the core.

In order to adjust the amount of depression of the depressing fork lever 46, the following features are specifically provided:

the reciprocating pushing mechanism 45 further comprises a limiting disc 47, a sliding short pin 49, a deflection disc 50, an adjusting sliding block 52 and an adjusting support 53, wherein the deflection disc 50 is fixedly connected with the output end of the second motor 54, the adjusting support 53 is fixedly connected with one side, far away from the second motor 54, of the deflection disc 50, the adjusting sliding block 52 is slidably connected with the adjusting support 53, the middle part of the adjusting screw 51 is in threaded connection with the adjusting sliding block 52, two ends of the adjusting screw 51 are respectively and rotatably connected with the adjusting support 53, the limiting disc 47 is fixedly connected with the adjusting sliding block 52, one end of the sliding short pin 49 is slidably connected with an annular groove on the surface of the limiting disc 47, and the other end of the sliding short pin 49 is hinged with the upper end of the pushing fork rod 46. After the second motor 54 is started, the second motor 54 can drive the deflection disc 50 to rotate, the deflection disc 50 drives the limiting disc 47 to rotate through the adjusting support 53 and the adjusting slide block 52, the limiting disc 47 can drive the push-down fork rod 46 to move through the sliding short pin 49, and when the push-down fork rod 46 moves, in order to adapt to the section thicknesses of different core rings, an operator can adjust the eccentricity of the limiting disc 47 and the deflection disc 50 through rotating the adjusting screw 51, so that the push-down amount of the push-down fork rod 46 is adjusted.

The theory of operation of this device is, when the device operates, screening charging tray 1 starts earlier and pushes a plurality of core circles in proper order in U type groove 3, and then second motor 54 starts and promotes the core circle downwards in the first unloading pipe 6 of U type groove 3 lower extreme, and in this process, the core circle can stack downwards in proper order, and operating personnel can adjust the displacement volume of pushing down fork rod 46 this moment to the stack height of control core circle, and then the quantity of the core circle of carrying at every turn is controlled.

In adjusting the push-down fork 46, an operator can adjust the amount of push-down of the push-down fork 46 by rotating the adjusting screw 51 to adjust the eccentricity of the limit disk 47 and the deflection disk 50.

When the core rings are gradually stacked, the pushing fork rod 46 pushes the carrying tube cover 11 to displace through the core rings (here, the carrying tube cover 11 at the lower end of the pushing fork rod 46 is not opened due to the existence of the pushing support rod 17, but descends integrally with the second discharging tube 10), at this time, the supporting base plate 8 and the supporting top plate 4 relatively displace, and the distance between the first discharging tube 6 and the second discharging tube 10 changes.

After the first blanking pipe 6 and the second blanking pipe 10 are relatively displaced, the second blanking pipe 10 drives the stop baffle 34 at the lower end of the U-shaped groove 3 to block the first blanking pipe 6, and at this time, a group of core rings are conveyed. Then, the first motor 42 is started and drives the accommodating disc 43 to rotate, when the accommodating disc 43 rotates, the accommodating disc 43 drives the supporting top disc 4 to rotate until the first blanking pipe 6 containing the core rings moves to the side of the accommodating iron frame 44, when the first blanking pipe 6 moves to the side of the accommodating iron frame 44, the core rings fall onto the accommodating iron frame 44 under the action of gravity, and at the moment, the core rings are conveyed and are accommodated in groups.

The foregoing examples merely illustrate one or more embodiments of the invention, which are described in greater detail and are not to be construed as limiting the scope of the invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (8)

1. Cable type steel wire coil core circle conveyor, its characterized in that includes:

screening a feeding disc (1);

the transfer conveying mechanism (2) is arranged at the side of the screening feeding disc (1), and comprises a U-shaped groove (3), a bearing top disc (4), a bearing chassis (8), a counting transfer mechanism (16), a first motor (42), a containing disc (43), a plurality of iron containing frames (44), two first blanking pipes (6), two second blanking pipes (10) and two anti-disengaging mechanisms (28), wherein the U-shaped groove (3) is fixedly connected with the output end of the screening feeding disc (1), the bearing top disc (4) is rotationally connected with the lower end of the U-shaped groove (3), the bearing chassis (8) is coaxially arranged at the lower end of the bearing top disc (4), the two first blanking pipes (6) are symmetrically arranged at the lower end of the bearing top disc (4), the two second blanking pipes (10) are respectively and slidably connected with the two first blanking pipes (6), the counting transfer mechanism (16) is connected with the bearing chassis (8), the two anti-disengaging mechanisms (28) are respectively connected with the iron containing frames (8) at the lower end of the bearing chassis (43) along the same circumference as the containing disc (43) and the lower end of the bearing chassis (43) is arranged at the lower end of the bearing chassis (43), the output end of the first motor (42) is fixedly connected with the accommodating disc (43);

the reciprocating pressing mechanism (45) is arranged above the supporting top plate (4) and can push the core ring to move in the first blanking pipe (6).

2. The cable-type bead ring core ring conveying device according to claim 1, characterized in that two blanking through holes (5) are formed in the supporting top disc (4), avoiding holes (7) are formed in the first blanking tube (6), blanking holes (9) are formed in the supporting base disc (8), the transferring and conveying mechanism (2) further comprises a limiting bearing ring (14), two bearing tube covers (11) and two bearing balls (13), the limiting bearing ring (14) is coaxially connected with the lower end of the supporting base disc (8) in a rotating mode, the two first blanking tubes (6) are respectively fixedly connected with the two blanking through holes (5) in a coaxial line mode, the two second blanking tubes (10) are respectively fixedly connected with the two blanking holes (9) in a coaxial line mode, the middle portions of the two bearing tube covers (11) are respectively hinged with the two second blanking tubes (10) through torsion springs, limiting parts (12) are respectively formed in the two bearing tube covers (11), the two bearing balls (13) are respectively connected with the two limiting parts (12) in a rotating mode, the limiting bearing ring (14) is formed in the circumferential direction, and the two bearing balls (15) can respectively abut against the limiting grooves (15) in the supporting top disc (4).

3. The cable type steel wire coil core ring conveying device according to claim 2, wherein the transfer conveying mechanism (2) further comprises a driving sleeve shaft (36), a reset spring (35), a driving main shaft (37), a power gear (38), a power residual tooth (39), a driving pulley (40) and a driven pulley (41), the driving sleeve shaft (36) is fixedly connected with the supporting top disc (4) in a coaxial line, the upper end of the driving main shaft (37) is fixedly connected with the driving sleeve shaft (36) in a key way, the driving pulley (40) is fixedly connected with the output end of the first motor (42) in a coaxial line, the driven pulley (41) is rotatably arranged at the side of the first motor (42) and is in transmission connection with the driving pulley (40) through a belt, the power residual tooth (39) is coaxially fixedly connected with the lower end of the driven pulley (41), the power gear (38) is rotatably arranged at the side of the power residual tooth (39), the lower end of the driving main shaft (37) is coaxially fixedly connected with the power gear (38), the reset spring (35) is sleeved outside the main shaft (37) in a coaxial line, and the reset spring (35) is abutted against one end of the driving sleeve (36).

4. The cable-type bead ring core ring conveying device according to claim 3, wherein the counting and transferring mechanism (16) comprises a pressing support rod (17), a limiting snap ring (18), a pressing rack (19), a pressing gear (20) and a reversing gear (21), the pressing support rod (17) is fixedly connected with the limiting bearing ring (14), the limiting snap ring (18) is fixedly connected with the lower end of the pressing support rod (17), the limiting snap ring (18) is rotationally connected with a driving sleeve shaft (36), the pressing rack (19) is fixedly connected with one side, far away from the limiting snap ring (18), of the pressing support rod (17), the pressing gear (20) is rotationally arranged beside the pressing rack (19) and meshed with the pressing rack (19), the reversing gear (21) is arranged on one side, far away from the pressing rack (19), of the reversing gear (21) is meshed with the pressing gear (20).

5. The cable-type bead ring core conveying device according to claim 4, wherein the counting and transferring mechanism (16) further comprises a first belt wheel (22), a second belt wheel (23), a first bevel gear (24), a second bevel gear (25), a transferring gear (26) and a driving gear ring (27), the first belt wheel (22) is coaxially fixedly connected with the reversing gear (21), the second belt wheel (23) is arranged above the first belt wheel (22) and is in transmission connection with the first belt wheel (22) through a belt, the first bevel gear (24) is coaxially fixedly connected with the second belt wheel (23), the second bevel gear (25) is meshed with the first bevel gear (24), the transferring gear (26) is coaxially fixedly connected with the second bevel gear (25), the driving gear ring (27) is coaxially and rotatably connected with the lower end of the supporting top disc (4), and the driving gear ring (27) is meshed with the transferring gear (26).

6. The cable-type steel wire coil core conveying device according to claim 5, wherein the anti-falling mechanism (28) further comprises two first gears (29), two ratchet wheels (30), two second gears (31), two driving gears (32), two driving racks (33) and two stop baffles (34), the two first gears (29) are rotatably arranged in the driving gear ring (27), the two first gears (29) are respectively meshed with the inner sides of the driving gear ring (27), one sides of the two ratchet wheels (30) are respectively fixedly connected with the two first gears (29) in a coaxial line, the two second gears (31) are respectively fixedly connected with the other sides of the two ratchet wheels (30), the two driving gears (32) are respectively meshed with the two second gears (31), the two driving racks (33) are respectively arranged beside the two driving gears (32) in a sliding mode, the two driving racks (33) are respectively meshed with the two driving gears (32), the two stop baffles (34) are respectively connected with the two lower driving racks (33) close to one ends of the two stop baffles (7) in a sliding mode, and the two stop baffles (7) are fixedly connected with one ends of the two stop baffles (7) in a sliding mode.

7. The cable type bead ring core ring conveying device according to claim 6, wherein the reciprocating pressing mechanism (45) further comprises a pressing fork rod (46), the pressing fork rod (46) is arranged above the U-shaped groove (3) in a vertical state, the pressing fork rod (46) is in sliding connection with the supporting curved seat (55) through the rod seat, and the lower end of the pressing fork rod (46) can prop against the core ring in the first blanking pipe (6).

8. The cable type steel wire coil core ring conveying device according to claim 7, wherein the reciprocating pressing mechanism (45) further comprises a limiting disc (47), a sliding short pin (49), a deflection disc (50), an adjusting sliding block (52) and an adjusting support (53), the deflection disc (50) is fixedly connected with the output end of the second motor (54), the adjusting support (53) is fixedly connected with one side, far away from the second motor (54), of the deflection disc (50), the adjusting sliding block (52) is slidably connected with the adjusting support (53), the middle part of the adjusting screw (51) is in threaded connection with the adjusting sliding block (52), two ends of the adjusting screw (51) are respectively in rotational connection with the adjusting support (53), the limiting disc (47) is fixedly connected with the adjusting sliding short pin (49), one end of the sliding short pin (49) is slidably connected with an annular groove on the surface of the limiting disc (47), and the other end of the sliding short pin is hinged with the upper end of the pressing fork rod (46).