CN110524612B

CN110524612B - Intelligent flow production device for resin anchoring agent

Info

Publication number: CN110524612B
Application number: CN201910801701.8A
Authority: CN
Inventors: 蒋美义; 王厚东; 陈方松; 王祺琦
Original assignee: Huainan Jinde Industry Co ltd
Current assignee: Huainan Jinde Industry Co ltd
Priority date: 2019-08-28
Filing date: 2019-08-28
Publication date: 2020-12-04
Anticipated expiration: 2039-08-28
Also published as: CN110524612A

Abstract

The invention discloses an intelligent flow production device for a resin anchoring agent, which comprises a workbench, a clamping device, a pushing device and a cutting device, wherein the workbench comprises a carriage for transporting the anchoring agent, a cutting frame for cutting the anchoring agent and a transporting frame for transporting the anchoring agent, the carriage is provided with the pushing device, and the pushing device is connected with the clamping device; compared with the prior art, the volume occupied by the whole cutting process is smaller, and the anchoring agents from the sliding frame can be cut off in sequence, so that the mode of flow production and processing is realized, and the efficiency is improved; when the anchoring agent moves to the connecting part of the cutting frame and the sliding frame, the end part of the anchoring agent is clamped between the adjacent guide plates and pushes the guide plates to rotate, so that the end part of the anchoring agent can be pushed into the conveying groove to be conveyed; the cutting knife is detachably arranged, so that the condition that the cutting process cannot be continued to cut due to rusting of the cutting knife is avoided.

Description

Intelligent flow production device for resin anchoring agent

Technical Field

The invention relates to the technical field of resin anchoring agent production, in particular to an intelligent flow production device for a resin anchoring agent.

Background

The resin anchoring agent is a viscous anchoring adhesive material prepared from unsaturated polyester resin, a curing agent, an accelerant and other auxiliary materials according to a certain proportion, is cut and packaged by a polyester film to be in a medicated roll shape, has the excellent performances of quick curing at normal temperature, high adhesive strength, reliable anchoring force, good durability and the like, is quick to bear, and has the anchoring performance similar to that of a steel bar embedded part. Has the characteristics of fast curing time, fast strength increase and high strength. After being installed, the anchor rod not only can bear load in time, but also has large anchoring force; the resin anchoring agent has strong adaptability and wide bonding objects. The special-shaped complex large-scale thin plate structure is bonded, various wood, metal, glass fiber reinforced plastic bodies and other rigid objects can be anchored, and the fatigue strength is good; in the production process of the resin anchoring agent, the anchoring agents packaged by adjacent finished products are generally mutually connected, so the resin anchoring agent needs to be removed through a series of processing after production, in the prior art, the produced anchoring agent is generally placed on a carrying frame manually and then is cut manually, errors can be caused during cutting, the anchoring agent is scattered, the working environment is polluted, the goods need to be carried into the carrying frame continuously during manual transportation, the transportation is very troublesome, the whole equipment is discontinuous, the time is wasted in the material transportation process, and the working efficiency is reduced.

Disclosure of Invention

The purpose of the invention can be realized by the following technical scheme: an intelligent flow production device for a resin anchoring agent comprises a workbench, a clamping device, a pushing device and a cutting device, wherein the workbench comprises a sliding frame for transporting the anchoring agent, a cutting frame for cutting the anchoring agent and a transporting frame for transporting the anchoring agent, the sliding frame is provided with the pushing device, the pushing device is connected with the clamping device, the upper end of the sliding frame is connected with one end of the cutting frame, the cutting frame is provided with the cutting device, the other end of the cutting frame is connected with the transporting frame, a conveying shaft is rotatably arranged on the transporting frame, the sliding frame and the cutting frame are provided with transporting grooves, and the tail ends of the transporting grooves are positioned on one side of the transporting frame;

the pushing device comprises a first motor, a conveying belt and a lead screw, a first supporting block is arranged on the lower surface of the sliding frame, the first motor is arranged on the first supporting block, the conveying belt is arranged at the output end of the first motor, the lead screw is arranged on the conveying belt in a transmission manner, two ends of the lead screw are rotatably arranged on the sliding frame, a sliding sleeve is sleeved on the surface of the lead screw in a threaded manner, and the sliding sleeve is connected with the clamping device;

the clamping device comprises an air cylinder, connecting plates, hinge rods and a frame plate, the upper end of the sliding sleeve is connected with the connecting plate on the upper side, the surface of the connecting plate on the upper side is provided with the air cylinder, the output end of the air cylinder is provided with a telescopic rod, the tail end of the telescopic rod is connected with the connecting plate on the lower side, the hinge rods are rotated between the adjacent connecting plates, the end parts of the two hinge rods are hinged, one side of the connecting plate on the lower side is movably provided with a clamping plate, and the hinge;

the cutting device comprises a second motor, a driving gear, a driven gear, a beam plate and a cutting knife, a bottom plate is welded on the lower surface of the cutting frame, the second motor is arranged on the bottom plate, the output end of the second motor rotates to form the driving gear, the driving gear is meshed with the driven gear to form the driving gear, a first rotating plate is arranged on one side of the driving gear and one side of the driven gear in a rotating mode, a second rotating plate is arranged on the cutting frame in a rotating mode, a rotating sleeve is arranged between the adjacent first rotating plate and the second rotating plate in a rotating mode, the beam plate is welded between the adjacent rotating sleeves in the same horizontal plane, and the movable clamp is arranged.

Preferably, the sliding chutes which are symmetrically distributed are formed in the surface of the sliding frame, the sliding chutes are penetrated through the upper ends of the sliding sleeves, the fixed blocks which are symmetrically distributed are arranged on the lower surface of the sliding frame, and the screw rod is rotatably arranged between the adjacent fixed blocks.

Preferably, the cutting frame and the bottom plate are welded with second supporting blocks, the second supporting blocks are respectively connected with one end of the first rotating plate and one end of the second rotating plate in a rotating mode, a cutting groove is formed in the cutting frame, and the cutting knife penetrates through the cutting groove.

Preferably, the surface of the bottom plate is provided with a through groove in a penetrating mode, and the beam plate and the driving gear penetrate through the through groove.

Preferably, the lower extreme welding of bottom plate has the supporting leg, and the lower extreme welding of transportation frame has the third supporting shoe, and the third supporting shoe is welded with the supporting leg.

Preferably, the cutting frame is welded with symmetrically arranged stop blocks at one end close to the sliding frame, a rotating drum is rotated between the stop blocks, guide plates are distributed on the surface of the rotating drum at equal intervals, and the guide plates are positioned above the conveying groove.

Preferably, the downside the one end of connecting plate is equipped with the spring, and the one end of spring is connected the setting with splint, and one side that splint are close to the spring is equipped with the connecting block, and the one end of hinge bar can contact the setting with the surface of connecting block.

Preferably, the beam plate is provided with a sliding groove and a clamping groove respectively, the sliding groove is distributed on two sides of the clamping groove, one end of the cutting knife is provided with a clamping block, the cross section of the clamping block is in an I shape, the clamping block is clamped in the clamping groove, a limiting block is arranged in the sliding groove in a sliding mode, and the limiting block is clamped in the clamping block.

Preferably, a pressure spring is fixed at the bottom of the sliding groove, one end of the pressure spring is connected with one end of the limiting block, and a shifting block is vertically arranged on one side of the limiting block.

The invention has the beneficial effects that:

1. compared with the prior art, the volume occupied by the whole cutting process is smaller, and the anchoring agents from the sliding frame can be cut off in sequence, so that the mode of flow production and processing is realized, and the efficiency is improved;

2. when the anchoring agent moves to the connecting part of the cutting frame and the sliding frame, the end part of the anchoring agent is clamped between the adjacent guide plates and pushes the guide plates to rotate, so that the end part of the anchoring agent can be pushed into the conveying groove to be conveyed;

3. the cutting knife is detachably arranged, so that the condition that the cutting process cannot be continued to cut due to rusting of the cutting knife is avoided;

4. the manufactured anchoring agent can be placed on the sliding frame and can be transported from bottom to top in sequence, the whole process does not need manual operation, the transportation is relatively safe, and the cutting can be directly carried out after the transportation, so that the time is saved;

5. compared with the prior art, the cut anchoring agent is taken out of the cutting frame without manual operation one by one, so that the manual output is reduced, and the efficiency is improved.

Drawings

The invention will be further described with reference to the accompanying drawings.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a side schematic view of the present invention;

FIG. 3 is a schematic view of the pushing device of the present invention;

FIG. 4 is a schematic view of the gripping apparatus of the present invention;

FIG. 5 is a schematic view of the cutting apparatus of the present invention;

FIG. 6 is a schematic view of a mount of the present invention;

fig. 7 is a schematic view of the beam plate of the present invention in connection with a cutting blade.

In the figure: 1 carriage, 11 chutes, 12 fixed blocks, 13 first supporting blocks, 2 cutting frames, 21 second supporting blocks, 22 supporting plates, 23 bottom plates, 231 through grooves, 24 supporting legs, 3 transportation frames, 31 third supporting blocks, 32 transmission shafts, 4 drums, 41 guide plates, 42 stoppers, 5 pushing devices, 51 first motors, 511 conveyor belts, 52 screw rods, 53 sliding sleeves, 6 clamping devices, 61 air cylinders, 62 telescopic rods, 63 hinge rods, 64 connecting plates, 641 springs, 65 clamping plates, 651 connecting blocks, 7 cutting devices, 71 second motors, 72 driving gears, 73 driven gears, 74 first rotating plates, 75 rotating sleeves, 8 beam plates, 81 limiting grooves, 82 pressure springs, 83 clamping grooves, 9 limiting blocks, 91 shifting blocks, 10 cutting knives and 101 clamping blocks.

Detailed Description

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

Referring to fig. 1-7, the present invention provides a technical solution: an intelligent flow production device for a resin anchoring agent comprises a workbench, a clamping device 6, a pushing device 5 and a cutting device 7, wherein the workbench comprises a sliding frame 1 for transporting the anchoring agent, a cutting frame 2 for cutting the anchoring agent and a transporting frame 3 for transporting the anchoring agent, the sliding frame 1 is provided with the pushing device 5, the pushing device 5 is connected with the clamping device 6, the pushing device 5 and the clamping device 6 are respectively arranged on the lower surface and the upper surface of the sliding frame 1, the upper end of the sliding frame 1 is connected with one end of the cutting frame 2, an included angle between the sliding frame 1 and the cutting frame 2 is not more than 30 degrees, the cutting device 7 is arranged on the cutting frame 2, the other end of the cutting frame 2 is connected with the transporting frame 3, a conveying shaft 32 is rotatably arranged on the transporting frame 3, transporting grooves are respectively arranged on the sliding frame 1 and the cutting frame 2, and the tail ends of the transporting grooves are positioned on one side of; when the processed anchoring agents sequentially slide into the conveying frame 3 one by one and can be conveyed through the rotating conveying rollers 32, compared with the prior art, the cut anchoring agents are not required to be taken out of the cutting frame 2 one by one manually, so that the manpower output is reduced, and the efficiency is improved;

the pushing device 5 comprises a first motor 51, a conveyor belt 511 and a screw rod 52, the lower surface of the carriage 1 is provided with first supporting blocks 13, the first motor 51 is arranged on the first supporting blocks 13, the cross section of each first supporting block 13 is L-shaped, the two first supporting blocks are symmetrically distributed on the lower surface of the carriage 1, the conveyor belt 511 is arranged at the output end of the first motor 51, the screw rod 52 is arranged on the conveyor belt 511 in a transmission manner, the two ends of the screw rod 52 are rotatably arranged on the carriage 1, a sliding sleeve 53 is sleeved on the surface of the screw rod 52 in a threaded manner, and the sliding sleeve 53 is connected with the clamping device 6; when the first motor 51 starts to work, the screw rod 52 is driven to rotate, the screw rod 52 rotates to drive the sliding sleeve 53 to move upwards, so that the clamping device 6 is driven to move, the manufactured anchoring agent can be placed on the sliding frame 1 and can be conveyed from bottom to top in sequence, the whole process does not need manual operation, the conveying is relatively safe, the cutting can be directly carried out after the conveying, and the time is saved;

the clamping device 6 comprises an air cylinder 61, a connecting plate 64, hinged rods 63 and a frame plate, the upper end of the sliding sleeve 53 is connected with the upper connecting plate 64, the surface of the upper connecting plate 64 is provided with the air cylinder 61, the output end of the air cylinder 61 is provided with a telescopic rod 62, the tail end of the telescopic rod 62 is connected with the lower connecting plate 64, the hinged rods 63 are rotated between the adjacent connecting plates 64, the end parts of the two hinged rods 63 are hinged, one side of the lower connecting plate 64 is movably provided with a clamping plate 65, and the hinged rods 63 push the clamping plate 65 to; when the anchoring agent is placed on the sliding frame 1, the air cylinder 61 starts to work and drives the distance between the adjacent connecting plates 64 to be shortened, at the moment, the hinged rod 63 pushes outwards and pushes the clamping plates 65 to move, and the adjacent clamping plates 65 can clamp the anchoring agent in the middle and move upwards under the driving of the pushing device 5 until the anchoring agent is transported to the cutting frame 2;

the cutting device 7 comprises a second motor 71, a driving gear 72, a driven gear 73, a beam plate 8 and a cutting knife 10, wherein the bottom plate 23 is welded on the lower surface of the cutting frame 2, the second motor 71 is arranged on the bottom plate 23, a supporting plate 22 is arranged on one side of the bottom plate 23, a rotating rod is welded at one end of the supporting plate 22, the tail end of the rotating rod is rotatably inserted on the driven gear 73 and plays a good supporting role for the driven gear 73, the driving gear 72 is rotated at the output end of the second motor 71, the driving gear 72 is meshed with the driven gear 73, a first rotating plate 74 is rotatably arranged on one side of the driving gear 72 and one side of the driven gear 73, a second rotating plate is rotatably arranged on the cutting frame 2, a rotating sleeve 75 is rotatably arranged between the adjacent first rotating plates 74 and the second rotating plate, the beam plate 8 is welded between the adjacent rotating sleeves 75 in the same horizontal plane, and the; when the anchoring agent moves to cutting frame 2, second motor 71 begins to work, and drive driving gear 72 and driven gear 73 and rotate, first rotor plate 74 and second rotor plate drive beam slab 8 and move this moment, when the coupling part of adjacent anchoring agent moves to between the adjacent beam slab 8, the cutting knife 10 that sets up on the adjacent beam slab 8 acts on this coupling part, thereby cut off it, adjacent anchoring agent separates naturally this moment, thereby accomplish the cutting, compare with prior art, the shared volume of whole cutting process is less, and can cut off the anchoring agent that comes from balladeur train 1 in proper order, realize the mode of flow production processing, thereby raise the efficiency.

The surface of the sliding frame 1 is provided with symmetrically distributed sliding grooves 11, the upper end of the sliding sleeve 53 penetrates through the sliding grooves 11, the lower surface of the sliding frame 1 is provided with symmetrically distributed fixed blocks 12, and the screw rod 52 is rotatably arranged between the adjacent fixed blocks 12.

All welded on cutting frame 2 and bottom plate 23 has second supporting shoe 21, and second supporting shoe 21 rotates with the one end of first rotor plate 74 and the one end of second rotor plate respectively to be connected, has seted up on cutting frame 2 and has cut the groove, and cutting knife 10 runs through and cuts the groove.

The surface of bottom plate 23 has run through and has seted up wearing groove 231, and roof beam board 8 and driving gear 72 all run through wearing groove 231.

Supporting legs 24 are welded at the lower end of the bottom plate 23, a third supporting block 31 is welded at the lower end of the transportation frame 3, and the third supporting block 31 is welded with the supporting legs 24.

One end of the cutting frame 2 close to the sliding frame 1 is welded with symmetrically arranged stop blocks 42, a rotating drum 4 rotates between the stop blocks 42, guide plates 41 are distributed on the surface of the rotating drum 4 at equal intervals, and the guide plates 41 are positioned above the conveying groove; when the anchoring agent moves to the connection part of the cutting frame 2 and the carriage 1, the end part of the anchoring agent is caught between the adjacent guide plates 41 and pushes the guide plates 41 to rotate, so that the end part of the anchoring agent can be pushed to the inside of the transport chute to be transported.

One end of the lower connecting plate 64 is provided with a spring 641, one end of the spring 641 is connected with the clamping plate 65, one side of the clamping plate 65 close to the spring 641 is provided with a connecting block 651, and one end of the hinge rod 63 can be in contact with the surface of the connecting block 651; after the transportation of the anchoring agent is completed, the cylinder 61 is closed, and the hinge rod 63 does not press the connection block 651 any more, thereby moving it back under the pulling force of the spring 641, thereby facilitating the next clamping.

A limiting groove 81 and a clamping groove 83 are respectively formed in the beam plate 8, the limiting groove 81 is distributed on two sides of the clamping groove 83, a clamping block 101 is arranged at one end of the cutting knife 10, the cross section of the clamping block 101 is in an I shape, the clamping block 101 is clamped in the clamping groove 83, a limiting block 9 is arranged in the limiting groove 81 in a sliding mode, and the limiting block 9 is clamped in the clamping block 101; the cutting knife 10 is detachably arranged, and the situation that the cutting knife 10 rusts to cause the cutting process to be incapable of continuing cutting is avoided.

A pressure spring 82 is fixed at the bottom of the limiting groove 81, one end of the pressure spring 82 is connected with one end of the limiting block 9, and a shifting block 91 is vertically arranged at one side of the limiting block 9; the pressure spring 82 pushes the limiting block 9, so that the limiting block 9 is clamped on the clamping block 101, and the stability of the cutting knife 10 during placement is improved.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Claims

1. An intelligent flow production device for resin anchoring agent comprises a workbench, a clamping device (6), a pushing device (5) and a cutting device (7), wherein the workbench comprises a carriage (1) for transporting the anchoring agent, a cutting frame (2) for cutting the anchoring agent and a transporting frame (3) for transporting the anchoring agent, the cutting device is characterized in that a pushing device (5) is arranged on the sliding frame (1), a clamping device (6) is connected onto the pushing device (5), the upper end of the sliding frame (1) is connected with one end of the cutting frame (2), a cutting device (7) is arranged on the cutting frame (2), the other end of the cutting frame (2) is connected with the transportation frame (3), a conveying shaft (32) is rotatably arranged on the transportation frame (3), transportation grooves are formed in the sliding frame (1) and the cutting frame (2), and the tail ends of the transportation grooves are located on one side of the transportation frame (3);

the pushing device (5) comprises a first motor (51), a conveying belt (511) and a screw rod (52), a first supporting block (13) is arranged on the lower surface of the sliding frame (1), the first motor (51) is arranged on the first supporting block (13), the conveying belt (511) is arranged at the output end of the first motor (51), the screw rod (52) is arranged on the conveying belt (511) in a transmission mode, two ends of the screw rod (52) are rotatably arranged on the sliding frame (1), a sliding sleeve (53) is sleeved on the surface of the screw rod (52) in a threaded mode, and the sliding sleeve (53) is connected with the clamping device (6);

the clamping device (6) comprises an air cylinder (61), a connecting plate (64), hinged rods (63) and a frame plate, the upper end of the sliding sleeve (53) is connected with the connecting plate (64) on the upper side, the surface of the connecting plate (64) on the upper side is provided with the air cylinder (61), the output end of the air cylinder (61) is provided with a telescopic rod (62), the tail end of the telescopic rod (62) is connected with the connecting plate (64) on the lower side, the hinged rods (63) are rotated between the adjacent connecting plates (64), the end parts of the two hinged rods (63) are hinged, one side of the connecting plate (64) on the lower side is movably provided with a clamping plate (65), and the hinged rods (63) push;

cutting device (7) include second motor (71), driving gear (72), driven gear (73), roof beam board (8) and cutting knife (10), the lower surface welding of cutting frame (2) has bottom plate (23), second motor (71) set up on bottom plate (23), the output of second motor (71) rotates there is driving gear (72), driving gear (72) and driven gear (73) mesh mutually and sets up, one side of driving gear (72) and driven gear (73) all rotates and is equipped with first commentaries on classics board (74), it has the second to rotate on cutting frame (2) and changes the board, it is equipped with commentaries on classics cover (75) to rotate between adjacent commentaries on classics cover (75) in the same horizontal plane, the welding has roof beam board (8) between adjacent commentaries on classics cover (75), the activity card is equipped with cutting knife (10) on the roof beam board (8).

2. The intelligent flow production device for the resin anchoring agent is characterized in that sliding grooves (11) are symmetrically distributed on the surface of the sliding frame (1), the upper end of the sliding sleeve (53) penetrates through the sliding grooves (11), fixing blocks (12) are symmetrically distributed on the lower surface of the sliding frame (1), and the screw rod (52) is rotatably arranged between the adjacent fixing blocks (12).

3. The intelligent flow production device for the resin anchoring agent according to claim 1, wherein a second supporting block (21) is welded to each of the cutting frame (2) and the bottom plate (23), the second supporting block (21) is rotatably connected to one end of the first rotating plate (74) and one end of the second rotating plate, a cutting groove is formed in the cutting frame (2), and the cutting knife (10) penetrates through the cutting groove.

4. The intelligent flow production device for the resin anchoring agent according to claim 1, wherein a through groove (231) is formed in the surface of the bottom plate (23) in a penetrating manner, and both the beam plate (8) and the driving gear (72) penetrate through the through groove (231).

5. The intelligent flow production device for the resin anchoring agent as claimed in claim 1, wherein the lower end of the bottom plate (23) is welded with supporting legs (24), the lower end of the transportation frame (3) is welded with a third supporting block (31), and the third supporting block (31) is welded with the supporting legs (24).

6. The intelligent flow production device for the resin anchoring agent is characterized in that symmetrically arranged stop blocks (42) are welded at one end, close to the carriage (1), of the cutting frame (2), rotary drums (4) are rotated between the stop blocks (42), guide plates (41) are distributed on the surfaces of the rotary drums (4) at equal intervals, and the guide plates (41) are located above the conveying grooves.

7. The intelligent flow production device for resin anchoring agent according to claim 1, characterized in that one end of the connecting plate (64) at the lower side is provided with a spring (641), one end of the spring (641) is connected with a clamping plate (65), one side of the clamping plate (65) close to the spring (641) is provided with a connecting block (651), and one end of the hinge rod (63) is in contact with the surface of the connecting block (651).

8. The intelligent flow production device for the resin anchoring agent according to claim 1, wherein the beam plate (8) is provided with a limiting groove (81) and a clamping groove (83), the limiting groove (81) is distributed on two sides of the clamping groove (83), one end of the cutting knife (10) is provided with a clamping block (101), the clamping block (101) is in an I-shaped cross section, the clamping block (101) is clamped inside the clamping groove (83), the limiting block (9) is slidably arranged inside the limiting groove (81), and the limiting block (9) is clamped inside the clamping block (101).

9. The intelligent flow production device for the resin anchoring agent according to claim 8, wherein a pressure spring (82) is fixed at the bottom of the limiting groove (81), one end of the pressure spring (82) is connected with one end of the limiting block (9), and a shifting block (91) is vertically arranged at one side of the limiting block (9).