CN211362982U - Numerical control five-axis linkage bridge type stone cutting machine - Google Patents

Abstract

The utility model discloses a five axle linkage bridge type stonecutter of numerical control, comprising a base plate, the installation piece is all installed at the both ends of bottom plate bottom, and the one end that the installation piece is close to the bottom plate all is provided with first spout, first spout is installed through the slider and is collected the box, collect the bottom of box and install the air pump, and the input of air pump installs the exhaust tube that extends to collection box inside, the internally mounted of collecting the box has the dust collecting net. The utility model discloses install first servo motor, first threaded rod, first nut, the second threaded rod, first splint and second splint, first servo motor drives the clockwise or anticlockwise rotation of second threaded rod through first threaded rod for first nut and the second nut in the first threaded rod and the second threaded rod outside can remove to both ends or intermediate position department simultaneously, thereby can press from both sides the stone material of different specifications tightly through first splint and second splint, and the fixed process operation of stone material is comparatively convenient.

Description

Numerical control five-axis linkage bridge type stone cutting machine

Technical Field

The utility model relates to a stonecutter equipment technical field specifically is a numerical control five-axis linkage bridge type stonecutter.

Background

The stone machine is a machine used for processing stone, a large number of stone machines and tools are needed in the stone process, and the machine, spare parts, tools, auxiliary materials, instruments and the like used by the stone machines form all machines of the whole stone production process, when the stone is cut, a numerical control five-axis linkage stone cutter is often used, the traditional numerical control five-axis linkage bridge type stone cutter cannot quickly and effectively fix the stones with different specifications when the stone is cut, the stone fixing process is complicated and has limited fixing effect and poor stability when the stone is cut, meanwhile, the chips and dust generated by cutting are accumulated on a bottom plate when the traditional numerical control five-axis linkage bridge type stone cutter is used for cutting, and workers are inconvenient to collect the chips and dust, therefore, the utility model provides a numerical control five-axis linkage bridge type stone cutter is used for solving above-mentioned problem.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a five axle linkage bridge type stonecutter of numerical control to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a numerical control five-axis linkage bridge type stone cutter comprises a bottom plate, wherein mounting blocks are mounted at two ends of the bottom plate, a first sliding groove is formed in one end, close to the bottom plate, of each mounting block, a collecting box is mounted at each first sliding groove through a sliding block, an air pump is mounted at the bottom of each collecting box, an air exhaust pipe extending into the corresponding collecting box is mounted at the input end of each air pump, a dust collecting net is mounted inside each collecting box, fixing plates are mounted at two ends of the bottom plate, first electromagnetic sliding rails are mounted at the tops of the fixing plates, a beam is mounted on each first electromagnetic sliding rail through a sliding block, a second electromagnetic sliding rail is mounted at the top of each beam, a mounting plate is mounted on each second electromagnetic sliding rail through a sliding block, a stepping motor is mounted at the top of the mounting plate, a first rotating shaft is mounted at the output end of the stepping motor, second servo motor is installed at the top of fall way, and the output of second servo motor installs the third threaded rod that extends to the inside of fall way, the third nut is installed to the outside screw thread of third threaded rod, and the both ends of third nut bottom all install the connecting rod, the fixed block is installed to the bottom of connecting rod, the rotating electrical machines is installed at the top of fixed block, and the output of rotating electrical machines installs the second pivot, cutting blade is installed to the bottom of second pivot, control panel is installed to one side of bottom plate, the one end that control panel one side was kept away from at the bottom plate top is installed first servo motor, and first threaded rod is installed to first servo motor's output, control panel's output pass through the wire respectively with first servo motor, first electromagnetism slide rail, second electromagnetism slide rail, step motor, air pump, The input end of the second servo motor is electrically connected with the input end of the rotating motor.

Preferably, the one end that first servo motor was kept away from to first threaded rod is installed the second threaded rod, and the outside screw thread of first threaded rod installs first nut, the outside screw thread of second threaded rod installs the second nut, first nut is close to one side of control panel and installs first splint, the second nut is close to one side of control panel and installs the second splint, the one end that control panel one side was kept away from at the bottom plate top is close to first servo motor is provided with the third spout, and the third spout installs first connecting block through the slider, first connecting block is connected with first nut, the one end that control panel one side was kept away from at the bottom plate top is provided with the fourth spout, and the fourth spout installs the second connecting block through the slider, the second connecting block is connected with the second nut.

Preferably, one side of the top of the bottom plate, which is close to the control panel, is provided with a collecting port, and the collecting port is internally and uniformly provided with a placing plate.

Preferably, both ends of the interior of the lifting pipe are provided with second sliding grooves, the second sliding grooves are provided with limiting blocks through sliding blocks, and one ends, far away from the second sliding grooves, of the limiting blocks are connected with third nuts.

Preferably, the handle is installed to one side that the collection box is close to control panel, and the outside cover of handle is equipped with the sponge cover.

Preferably, the shock absorption supporting legs are installed on two sides of the bottom of the fixing plate, and the shock absorption pads are installed on the bottoms of the shock absorption supporting legs.

Compared with the prior art, the beneficial effects of the utility model are that: the numerical control five-axis linkage bridge type stone cutting machine is provided with a first servo motor, a first threaded rod, a first nut, a second threaded rod, a first clamping plate and a second clamping plate, wherein the first servo motor drives the second threaded rod to rotate clockwise or anticlockwise through the first threaded rod, so that the first nut and the second nut on the outer sides of the first threaded rod and the second threaded rod can move towards two ends or middle positions simultaneously, stone materials with different specifications can be clamped through the first clamping plate and the second clamping plate, the stone materials are convenient to fix, the fixing effect of the device is better, the stability is better, meanwhile, the device is provided with a dust collecting net, an exhaust pipe, an air pump and a collecting box, the air pump exhausts air through the exhaust pipe, dust attached to a placing plate is collected by being pumped into the inner part of the collecting box, the collecting box is pulled outwards through a first chute, and the dust on the dust collecting net can be cleaned, the worker can conveniently collect the chips and dust generated by cutting the stone.

Drawings

Fig. 1 is a schematic front sectional view of the present invention;

fig. 2 is a schematic front view of the present invention;

fig. 3 is a schematic cross-sectional view of the elevator tube of the present invention;

FIG. 4 is a schematic side cross-sectional view of a cross beam of the present invention;

fig. 5 is a schematic top view of the bottom plate of the present invention.

In the figure: 1. a base plate; 2. a first servo motor; 3. a first threaded rod; 4. a fixing plate; 5. a first electromagnetic slide rail; 6. a second electromagnetic slide rail; 7. a stepping motor; 8. a first chute; 9. a first nut; 10. a first connection block; 11. a collection port; 12. placing the plate; 13. a dust collecting net; 14. an air exhaust pipe; 15. an air pump; 16. a collection box; 17. a second nut; 18. a second connecting block; 19. a first rotating shaft; 20. mounting a plate; 21. a cross beam; 22. a second threaded rod; 23. mounting blocks; 24. a first splint; 25. a second splint; 26. a control panel; 27. a second servo motor; 28. a lifting pipe; 29. a rotating electric machine; 30. a connecting rod; 31. a cutting blade; 32. a second rotating shaft; 33. a fixed block; 34. a second chute; 35. a third threaded rod; 36. a limiting block; 37. a third nut; 38. a third chute; 39. and a fourth chute.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides an embodiment: a numerical control five-axis linkage bridge type stone cutting machine comprises a bottom plate 1, wherein mounting blocks 23 are mounted at two ends of the bottom plate 1, a first sliding groove 8 is formed in one end, close to the bottom plate 1, of each mounting block 23, a collecting box 16 is mounted on each first sliding groove 8 through a sliding block, an air pump 15 is mounted at the bottom of each collecting box 16, the type of each air pump 15 can be VCH1028, an air exhaust pipe 14 extending into each collecting box 16 is mounted at the input end of each air pump 15, a dust collecting net 13 is mounted inside each collecting box 16, fixing plates 4 are mounted at two ends of the bottom plate 1, first electromagnetic slide rails 5 are mounted at the tops of the fixing plates 4, a cross beam 21 is mounted on each first electromagnetic slide rail 5 through a sliding block, a second electromagnetic slide rail 6 is mounted at the top of the cross beam 21, a mounting plate 20 is mounted on each second electromagnetic slide rail 6 through a sliding block, a stepping motor 7 is, a first rotating shaft 19 is installed at the output end of the stepping motor 7, an elevating pipe 28 is installed at one end of the first rotating shaft 19, which is far away from the stepping motor 7, a second servo motor 27 is installed at the top of the elevating pipe 28, where the model of the second servo motor 27 can be SGRL-06, a third threaded rod 35 extending to the interior of the elevating pipe 28 is installed at the output end of the second servo motor 27, a third nut 37 is installed at the outer side of the third threaded rod 35 in a threaded manner, connecting rods 30 are installed at both ends of the bottom of the third nut 37, a fixed block 33 is installed at the bottom of the connecting rods 30, a rotating motor 29 is installed at the top of the fixed block 33, where the model of the rotating motor 29 can be Y90S-2, a second rotating shaft 32 is installed at the output end of the rotating motor 29, a cutting blade 31 is installed at the bottom of the second rotating shaft 32, a control panel 26 is installed at one side of the, here, the model of the first servo motor 2 may be SGRL-06, the first threaded rod 3 is installed at the output end of the first servo motor 2, and the output end of the control panel 26 is electrically connected to the input ends of the first servo motor 2, the first electromagnetic slide rail 5, the second electromagnetic slide rail 6, the stepping motor 7, the air pump 15, the second servo motor 27 and the rotating motor 29 through wires.

In this implementation:

further, a second threaded rod 22 is installed at one end of the first threaded rod 3 far away from the first servo motor 2, a first nut 9 is installed at the outer side thread of the first threaded rod 3, a second nut 17 is installed at the outer side thread of the second threaded rod 22, a first clamping plate 24 is installed at one side of the first nut 9 close to the control panel 26, a second clamping plate 25 is installed at one side of the second nut 17 close to the control panel 26, a third sliding groove 38 is arranged at one end of the top of the bottom plate 1 far away from the control panel 26 and close to the first servo motor 2, a first connecting block 10 is installed on the third sliding groove 38 through a sliding block, the first connecting block 10 is connected with the first nut 9, a fourth sliding groove 39 is arranged at one end of the top of the bottom plate 1 far away from the control panel 26 and far away from the first servo motor 2, a second connecting block 18 is installed on the fourth sliding groove 39 through a sliding block, the second, first servo motor 2 drives second threaded rod 22 clockwise or anticlockwise through first threaded rod 3 for first nut 9 and the second nut 17 in the first threaded rod 3 and the second threaded rod 22 outside can remove to both ends or intermediate position department simultaneously, thereby can press from both sides the stone material of different specifications tightly through first splint 24 and second splint 25, and the fixed process operation of stone material is comparatively convenient, and the fixed effect of device is better, and stability is better.

Further, one side of the top of the bottom plate 1, which is close to the control panel 26, is provided with a collecting opening 11, and a placing plate 12 is uniformly arranged inside the collecting opening 11, so that dust and debris can enter the collecting box 16 through the collecting opening 11 for collection.

Further, the inside both ends of fall pipe 28 all are provided with second spout 34, and stopper 36 is all installed through the slider to second spout 34, and stopper 36 keeps away from the one end of second spout 34 and all is connected with third nut 37, and stopper 36 can carry on spacingly to third nut 37, places third nut 37 and follows third threaded rod 35 and rotate together for third nut 37 can all reciprocate in the third threaded rod 35 outside.

Further, a handle is installed on one side of the collecting box 16 close to the control panel 26, and a sponge sleeve is sleeved on the outer side of the handle, so that the collecting box 16 can be conveniently drawn out from the lower side of the bottom plate 1.

Furthermore, the shock absorption supporting legs are installed on two sides of the bottom of the fixing plate 4, and the shock absorption pads are installed on the bottoms of the shock absorption supporting legs, so that the stability of the device is improved.

The working principle is as follows: when the stone cutting device is used, the device is firstly powered on, then the stone to be cut is placed on the placing plate 12, the first servo motor 2 is controlled to be started through the control panel 26, the first servo motor 2 drives the second threaded rod 22 to rotate clockwise through the first threaded rod 3, the first nut 9 on the outer side of the first threaded rod 3 and the second nut 17 on the outer side of the second threaded rod 22 move towards the middle position through threads simultaneously, the first clamping plate 24 and the second clamping plate 25 are tightly attached to the outer side of the stone, the stone can be clamped tightly, then the air pump 15 and the rotating motor 29 are started through the control panel 26, the rotating motor 29 drives the cutting blade 31 to rotate through the second rotating shaft 32, the stone is cut, the air pump 15 pumps air through the exhaust pipe 14, dust and debris generated by cutting are pumped into the collecting box 16, and the dust and the debris are collected through the dust collecting net 13, in the cutting process, a user can control the first electromagnetic slide rail 5 to drive the beam 21 to move back and forth through the control panel 26, control the second electromagnetic slide rail 6 to drive the mounting plate 20 to move in the horizontal direction through the control panel 26, adjust the cutting position of the stone material, and control the start of the stepping motor 7 through the control panel 26. The stepping motor 7 drives the lifting pipe 28 to rotate by a fixed angle through the first rotating shaft 19, so that the cutting angle can be adjusted, when the height of the cutting blade 31 needs to be adjusted, a worker can start the second servo motor 27 through the control panel 26, so that the second servo motor 27 drives the third threaded rod 35 to rotate clockwise or anticlockwise, so that the third nut 37 moves upwards or downwards outside the third threaded rod 35 through threads, so that the cutting blade 31 can move upwards or downwards, the adjustment process of the height of the cutting blade 31 is realized, after the cutting is finished, the air pump 15 and the rotating motor 29 are closed through the control panel 26, then the control panel 26 controls the first servo motor 2 to start, so that the first servo motor 2 drives the second threaded rod 22 to rotate anticlockwise through the first threaded rod 3, the first nut 9 outside the first threaded rod 3 and the second nut 17 outside the second threaded rod 22 move towards two ends through threads simultaneously, make first splint 24 and second splint 25 keep away from the stone material to can take off the stone material from bottom plate 1, then outside pulling collection box 16, make collection box 16 slide on first spout 8, take collection box 16 out from bottom plate 1 below, alright clear up dust collection net 13, thereby be convenient for collect the piece and the dust that the cutting produced.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. The utility model provides a five axle linkage bridge type stonecutter of numerical control, includes bottom plate (1), its characterized in that: the dust collector is characterized in that mounting blocks (23) are mounted at two ends of the bottom plate (1), one end, close to the bottom plate (1), of each mounting block (23) is provided with a first sliding groove (8), each collecting box (16) is mounted through a slider, an air pump (15) is mounted at the bottom of each collecting box (16), an air suction pipe (14) extending into each collecting box (16) is mounted at the input end of each air pump (15), a dust collecting net (13) is mounted inside each collecting box (16), fixing plates (4) are mounted at two ends of the bottom plate (1), first electromagnetic slide rails (5) are mounted at the tops of the fixing plates (4), a cross beam (21) is mounted on each first electromagnetic slide rail (5) through a slider, a second electromagnetic slide rail (6) is mounted at the tops of the cross beams (21), and mounting plates (20) are mounted on the second electromagnetic slide rails (6) through sliders, and step motor (7) is installed at the top of mounting panel (20), first pivot (19) is installed to the output of step motor (7), and step motor (7) was kept away from in first pivot (19) one end installs fall way (28), second servo motor (27) are installed at the top of fall way (28), and the output of second servo motor (27) installs and extend to inside third threaded rod (35) of fall way (28), third nut (37) are installed to the outside screw thread of third threaded rod (35), and connecting rod (30) are all installed at the both ends of third nut (37) bottom, fixed block (33) are installed to the bottom of connecting rod (30), rotating electrical machines (29) are installed at the top of fixed block (33), and second pivot (32) are installed to the output of rotating electrical machines (29), cutting blade (31) are installed to the bottom of second pivot (32), control panel (26) are installed to one side of bottom plate (1), bottom plate (1) top is kept away from the one end of control panel (26) one side and is installed first servo motor (2), and first threaded rod (3) are installed to the output of first servo motor (2), the output of control panel (26) passes through the wire respectively with the input electric connection of first servo motor (2), first electromagnetism slide rail (5), second electromagnetism slide rail (6), step motor (7), air pump (15), second servo motor (27) and rotating electrical machines (29).

2. The numerical control five-axis linkage bridge type stone cutting machine according to claim 1, characterized in that: the first threaded rod (3) is far away from one end of the first servo motor (2) and is provided with a second threaded rod (22), the outer side of the first threaded rod (3) is provided with a first nut (9) in a threaded manner, the outer side of the second threaded rod (22) is provided with a second nut (17) in a threaded manner, one side, close to the control panel (26), of the first nut (9) is provided with a first clamping plate (24), one side, close to the control panel (26), of the second nut (17) is provided with a second clamping plate (25), one side, far away from the control panel (26), of the top of the bottom plate (1) is provided with a third sliding groove (38), the third sliding groove (38) is provided with a first connecting block (10) through a sliding block, the first connecting block (10) is connected with the first nut (9), one end, far away from the first servo motor (2), of the side, far away from the control panel (26), of the top of the bottom plate (1) is provided with, and a second connecting block (18) is installed on the fourth sliding groove (39) through a sliding block, and the second connecting block (18) is connected with a second nut (17).

3. The numerical control five-axis linkage bridge type stone cutting machine according to claim 1, characterized in that: one side of the top of the bottom plate (1) close to the control panel (26) is provided with a collecting opening (11), and a placing plate (12) is uniformly arranged in the collecting opening (11).

4. The numerical control five-axis linkage bridge type stone cutting machine according to claim 1, characterized in that: the inside both ends of fall pipe (28) all are provided with second spout (34), and stopper (36) are all installed through the slider in second spout (34), the one end that second spout (34) were kept away from in stopper (36) all is connected with third nut (37).

5. The numerical control five-axis linkage bridge type stone cutting machine according to claim 1, characterized in that: the handle is installed to one side that collection box (16) is close to control panel (26), and the outside cover of handle is equipped with the sponge cover.

6. The numerical control five-axis linkage bridge type stone cutting machine according to claim 1, characterized in that: damping support legs are arranged on two sides of the bottom of the fixing plate (4), and damping cushions are arranged at the bottoms of the damping support legs.

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