CN113600897A

CN113600897A - Intelligent numerical control milling machine with power-off structure and use method thereof

Info

Publication number: CN113600897A
Application number: CN202110999560.2A
Authority: CN
Inventors: 朱威
Original assignee: Individual
Current assignee: Guangdong Guanghe Intelligent Equipment Co ltd
Priority date: 2021-08-29
Filing date: 2021-08-29
Publication date: 2021-11-05
Anticipated expiration: 2041-08-29
Also published as: CN113600897B

Abstract

The invention relates to the field of intelligent numerical control milling machines, in particular to an intelligent numerical control milling machine with a power-off structure, which comprises a bottom plate, wherein the upper end of the bottom plate is fixedly connected with an installation mechanism, a fourth bevel gear, a fifth bevel gear, a driving rod and a second gear are arranged to be meshed to drive a first gear and a first rotating rod, a threaded rod can be driven to rotate by the first bevel gear, the second bevel gear and the third bevel gear, a threaded sleeve and a second clamping plate can be driven to move under the sliding limiting action of a second sliding chute and a sliding rod, a processing block can be clamped conveniently, stably and quickly by matching with the first clamping plate, the clamping speed is high, the labor intensity of workers is reduced, when the abnormal work of a milling cutter is sensed by arranging two sensors, a stepping motor is started by a power supply, the stepping motor can lead a connecting wire core to leave from a first wire core and a second wire through a power-off rod and a power-off plate, therefore, the driving motor can be powered off, and danger is avoided.

Description

Intelligent numerical control milling machine with power-off structure and use method thereof

Technical Field

The invention relates to the field of intelligent numerical control milling machines, in particular to an intelligent numerical control milling machine with a power-off structure and a using method thereof.

Background

The intelligent numerical control milling machine is also called CNC milling machine, English means a milling machine controlled by electronic counting digitalized signals, the intelligent numerical control milling machine is an automatic processing device developed on the basis of a common milling machine, the processing technology of the intelligent numerical control milling machine and the automatic processing device are basically the same, the structure of the intelligent numerical control milling machine is similar, and the intelligent numerical control milling machine is divided into two categories of a tool magazine without tools and a tool magazine with tools. Wherein the numerical control milling machine with the tool magazine is also called as a machining center.

Present intelligent numerically controlled fraise machine often all is through artifical centre gripping machined part, need the workman constantly to press from both sides tightly, dismantle again after processing finishes, not only clamping speed is slow, and increase workman's intensity of labour, reduce machining efficiency, present intelligent numerically controlled fraise machine is in case set up processing in the decline in-process can not adjust milling cutter's position simultaneously, processing flexibility is low like this, can not use in a flexible way as required, and present intelligent numerically controlled fraise machine often can not cut off the power supply fast when processing the mistake, thereby lead to extravagant machined part, and increase the danger of workman's processing, the security performance is low.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides an intelligent numerical control milling machine with a power-off structure and a using method thereof.

The technical scheme adopted by the invention for solving the technical problems is as follows: an intelligent numerical control milling machine with a power-off structure comprises a bottom plate, wherein the upper end of the bottom plate is fixedly connected with an installation mechanism, the interior of the installation mechanism is rotatably connected with a clamping mechanism, the exterior of one side of the installation mechanism is fixedly connected with a driving mechanism, the driving mechanism is meshed and connected with the clamping mechanism, the inner side wall of one side, away from the clamping mechanism, of the installation mechanism is rotatably connected with a transmission mechanism, one side, close to the clamping mechanism, of the transmission mechanism is meshed and connected with a punching and milling mechanism, and the upper end of the driving mechanism is fixedly connected with a power-off mechanism;

the mounting mechanism comprises a mounting frame, the mounting frame is fixedly connected to the upper surfaces of two sides of the bottom plate, a first mounting hole is formed in the side wall of one side of the mounting frame, which is close to the lower end of the mounting frame, in a penetrating manner, a first sliding groove is formed in one side of the top end of the mounting frame, which is far away from the first mounting hole, in addition, an mounting box is fixedly connected to the upper surface of the bottom plate, which is positioned in the middle of the mounting frame, a second mounting hole is formed in one side of the mounting box, which is close to the first mounting hole, in a penetrating manner, a second sliding groove is formed in one side of the mounting box, a mounting opening is formed in the wall of the mounting box, which is positioned at the upper end of the second sliding groove, in a penetrating manner, and a first clamping plate is fixedly connected to the upper surface of one side of the mounting box, which is far away from the mounting opening;

the clamping mechanism comprises a first rotating rod, the first rotating rod is rotatably connected in a second mounting hole through a bearing, one side of the first rotating rod, which is far away from the first mounting hole, is fixedly connected with a first bevel gear, the inner box wall of the mounting box bottom, which is near one side of the first bevel gear, is rotatably connected with a second rotating rod through a bearing, the upper end of the second rotating rod is fixedly connected with a second bevel gear, the second bevel gear is meshed and connected with the lower end of the first bevel gear, the inner box wall of the mounting box, which is far away from one side of the first bevel gear, is rotatably connected with a threaded rod through a bearing, one side of the threaded rod, which is near the second bevel gear, is fixedly connected with a third bevel gear, the third bevel gear is meshed and connected with one side, which is far away from the first bevel gear, and the wall of the threaded rod is in threaded connection with a threaded sleeve, one side fixedly connected with slide bar that the thread bush is close to the second spout, one side that the slide bar is close to the second spout extends to in the second spout and sliding connection is in the second spout, thread bush upper end fixedly connected with spinal branch vaulting pole, the upper end of the support bar passes the installing port and extends to the install bin outside and a fixedly connected with second splint, a first gear of one side fixedly connected with of first conical tooth wheel is kept away from to first spinal branch vaulting pole.

The driving mechanism comprises a driving plate which is fixedly connected to the outer side wall of the upper end of the mounting frame close to the first mounting hole, the lower surface of the driving plate is fixedly connected with a driving motor, the output end of the driving motor is fixedly connected with a fourth bevel gear, a driving rod is rotatably connected in a first mounting hole at the lower end of the fourth bevel gear through a bearing, a fifth bevel gear is fixedly connected with one side rod wall of the driving rod close to the fourth bevel gear, the fifth bevel gear is meshed and connected with the lower end of the fourth bevel gear, one side of the driving rod, which is far away from the fifth bevel gear, passes through the first mounting hole, extends into the mounting frame and is fixedly sleeved with a first driving wheel, and one side of the driving rod close to the first driving wheel is fixedly connected with a second gear, and the second gear is meshed and connected with the first gear.

The transmission mechanism comprises a transmission rod, the transmission rod is rotatably connected with the inner side wall of the upper end of the mounting frame, which is located on one side of the far away first mounting hole, through a bearing, a second transmission wheel is fixedly sleeved on the rod wall of the transmission rod and the position corresponding to the first transmission wheel, the second transmission wheel and the first transmission wheel are jointly in transmission connection with a belt, and one side of the transmission rod, which is far away from the second transmission wheel, is fixedly connected with a sixth bevel gear.

Be close to the mounting bracket top inside wall of sixth conical gear one side is rotated through the bearing and is connected with a dwang, a seventh conical gear has all been cup jointed fixedly to the pole wall of the corresponding position of dwang and sixth conical gear, seventh conical gear meshing is connected on sixth conical gear, third gear of pole wall fixedly connected with under the dwang.

Towards milling mechanism includes a slide, slide sliding connection is in first spout, just a rack plate of slide lower extreme fixedly connected with, rack plate meshing connects on the third gear.

The rack plate lower surface fixedly connected with telescopic cylinder, telescopic cylinder output end swing joint has a piston rod, a movable plate of piston rod lower extreme fixedly connected with, movable plate lower surface both sides fixed mounting has two sensors, just a milling cutter of movable plate lower extreme center department fixedly connected with.

The power-off mechanism comprises a power supply, the power supply is fixedly connected to the upper surface of the drive plate, the power supply is electrically connected with the two sensors, the power supply is electrically connected with the drive motor and the telescopic cylinder, the lower end of one side of the power supply, which is far away from the mounting frame, is fixedly connected with a mounting plate, one side of the mounting plate is provided with a power-off groove, one side of the power-off groove, which is close to the power supply, is fixedly provided with a first wire core, the first wire core is electrically connected with the power supply, one side of the power-off groove, which is far away from the power supply, is fixedly provided with a second wire core, the lower end of the second wire core extends out of the mounting plate and is fixedly arranged on the drive motor, the outer side wall of the power supply at the upper end of the mounting plate is fixedly connected with a stepping motor, the output end of the stepping motor is fixedly connected with a power-off rod, one side of the power-off rod, which is far away from the stepping motor, is fixedly connected with a power-off plate, the lower end of the power-off board extends into the power-off groove and is fixedly connected with a connecting wire core, and two sides of the connecting wire core are abutted to the first wire core and the second wire core.

A use method of an intelligent numerical control milling machine with a power-off structure comprises the following steps:

the first step is as follows: firstly, a workpiece is placed on the upper surface of the installation box, then a driving motor is started, the output end of the driving motor can be meshed with a fourth bevel gear, a fifth bevel gear, a driving rod and a second gear to drive a first gear and a first rotating rod, so that a threaded rod can be driven to rotate by the first bevel gear, the second bevel gear and the third bevel gear, a threaded sleeve and a second clamping plate can be driven to move under the sliding limiting action of a second sliding groove and a sliding rod, and the first clamping plate is matched to conveniently, stably and quickly clamp a processing block;

the second step is that: the second transmission wheel, the transmission rod and the sixth conical gear are driven to rotate through the first transmission wheel and the belt, so that the rotating rod and the third gear are driven to rotate under the action of the seventh conical gear, the rack plate can be driven to move under the action of the first sliding groove and the sliding plate, the position of the milling cutter is conveniently adjusted, and then the milling cutter is driven to descend through the telescopic cylinder and the piston rod, so that the milling cutter is conveniently and quickly machined;

the third step: when two sensors sense the milling cutter abnormal work, the stepping motor can be started through the power supply, and the stepping motor can leave the connecting wire core from the first wire core and the second wire core through the power-off pole and the power-off plate, so that the driving motor can be powered off, and dangers are avoided.

The invention has the beneficial effects that:

(1) according to the intelligent numerical control milling machine with the power-off structure and the using method thereof, the fourth bevel gear, the fifth bevel gear, the driving rod and the second gear are arranged to be meshed with each other to drive the first gear and the first rotating rod, so that the threaded rod can be driven to rotate by the first bevel gear, the second bevel gear and the third bevel gear, the threaded sleeve and the second clamping plate can be driven to move under the sliding limiting action of the second sliding groove and the sliding rod, the machining block can be conveniently, stably and quickly clamped by matching with the first clamping plate, the clamping speed is high, and the labor intensity of workers is reduced.

(2) According to the intelligent numerical control milling machine with the power-off structure and the using method thereof, the first transmission wheel and the belt are arranged to drive the second transmission wheel, the transmission rod and the sixth conical gear to rotate, so that the rotating rod and the third gear are driven to rotate under the action of the seventh conical gear, the gear plate can be driven to move under the action of the first sliding groove and the sliding plate, the position of the milling cutter can be conveniently adjusted, then the milling cutter is driven to descend through the telescopic cylinder and the telescopic rod, and the rapid processing is convenient.

(3) According to the intelligent numerical control milling machine with the power-off structure and the using method thereof, the two sensors are arranged, so that when the milling cutter is sensed to work abnormally, the stepping motor is started through the power supply, the stepping motor can enable the connecting wire core to leave from the first wire core and the second wire core through the power-off rod and the power-off plate, the driving motor can be powered off, and dangers are avoided.

Drawings

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

FIG. 1 is a schematic view of an overall cross-sectional structure of an intelligent numerically controlled milling machine with a power-off structure according to the present invention;

FIG. 2 is an enlarged schematic structural view of a portion A in FIG. 1 of an intelligent numerically controlled milling machine with a power-off structure according to the present invention;

FIG. 3 is a schematic side sectional structural view of an installation box and a threaded sleeve of an intelligent numerically controlled milling machine with a power-off structure according to the present invention;

FIG. 4 is an enlarged schematic structural diagram of a portion B in FIG. 1 of an intelligent numerically controlled milling machine with a power-off structure according to the present invention;

FIG. 5 is a schematic structural diagram of a power-off mechanism in the intelligent numerically controlled milling machine with the power-off structure according to the present invention;

FIG. 6 is a schematic structural diagram of a cross section along the direction C-C in FIG. 1 of an intelligent numerically controlled milling machine with a power-off structure according to the present invention;

FIG. 7 is a schematic cross-sectional view along the direction D-D of FIG. 1 of an intelligent numerically controlled milling machine with a power-off structure according to the present invention;

fig. 8 is a schematic view of a top cross-sectional structure of an installation box in an intelligent numerically controlled milling machine with a power-off structure according to the present invention.

In the figure: 1. a base plate; 2. an installation mechanism; 21. a mounting frame; 22. a first mounting hole; 23. a first chute; 24. installing a box; 25. a second mounting hole; 26. a second chute; 27. an installation port; 28. a first splint; 3. a clamping mechanism; 31. a first rotating lever; 32. a first bevel gear; 33. a second rotating rod; 34. a second bevel gear; 35. a threaded rod; 36. a third bevel gear; 37. a threaded sleeve; 38. a slide bar; 39. a support bar; 310. a second splint; 311. a first gear; 4. a drive mechanism; 41. a drive plate; 42. a drive motor; 43. a fourth bevel gear; 44. a drive rod; 45. a fifth bevel gear; 46. a first drive pulley; 47. a second gear; 5. a transmission mechanism; 51. a transmission rod; 52. a second transmission wheel; 53. a belt; 54. a sixth bevel gear; 55. rotating the rod; 56. a seventh bevel gear; 57. a third gear; 6. a punching and milling mechanism; 61. a slide plate; 62. a rack plate; 63. a telescopic cylinder; 64. a piston rod; 65. moving the plate; 66. a sensor; 67. milling cutters; 7. a power-off mechanism; 71. a power source; 72. mounting a plate; 73. a power-off slot; 74. a first wire core; 75. a second wire core; 76. a stepping motor; 77. breaking the electric pole; 78. a power-off board; 79. and connecting the wire core.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

As shown in fig. 1-8, the intelligent numerically controlled milling machine with the power-off structure according to the present invention comprises a bottom plate 1, wherein an installation mechanism 2 is fixedly connected to the upper end of the bottom plate 1, a clamping mechanism 3 is rotatably connected to the inside of the installation mechanism 2, a driving mechanism 4 is fixedly connected to the outside of one side of the installation mechanism 2, the driving mechanism 4 is engaged and connected to the clamping mechanism 3, a transmission mechanism 5 is rotatably connected to the inner side wall of one side of the installation mechanism 2 away from the clamping mechanism 3, a milling mechanism 6 is engaged and connected to one side of the transmission mechanism 5 close to the clamping mechanism 3, and a power-off mechanism 7 is fixedly connected to the upper end of the driving mechanism 4;

the mounting mechanism 2 comprises a mounting frame 21, the mounting frame 21 is fixedly connected to the upper surfaces of two sides of the bottom plate 1, a first mounting hole 22 is formed in one side wall of the mounting frame 21 close to the lower end in a penetrating mode, a first sliding groove 23 is formed in one side of the top end of the mounting frame 21 far away from the first mounting hole 22, a mounting box 24 is fixedly connected to the upper surface of the bottom plate 1 in the middle of the mounting frame 21, a second mounting hole 25 is formed in one side of the mounting box 24 close to the first mounting hole 22 in a penetrating mode, a second sliding groove 26 is formed in one side of the mounting box 24, a mounting opening 27 is formed in the wall of the mounting box 24 at the upper end of the second sliding groove 26 in a penetrating mode, and a first clamping plate 28 is fixedly connected to the upper surface of one side of the mounting box 24 far away from the mounting opening 27;

the clamping mechanism 3 comprises a first rotating rod 31, the first rotating rod 31 is rotatably connected in the second mounting hole 25 through a bearing, a first bevel gear 32 is fixedly connected to one side of the first rotating rod 31 far away from the first mounting hole 22, a second rotating rod 33 is rotatably connected to the inner wall of the bottom end of the mounting box 24 near one side of the first bevel gear 32 through a bearing, a second bevel gear 34 is fixedly connected to the upper end of the second rotating rod 33, the second bevel gear 34 is meshed and connected to the lower end of the first bevel gear 32, a threaded rod 35 is rotatably connected to the inner wall of the mounting box 24 far away from one side of the first bevel gear 32 through a bearing, a third bevel gear 36 is fixedly connected to one side of the threaded rod 35 near the second bevel gear 34, the third bevel gear 36 is meshed and connected to one side far away from the first bevel gear 32, and a threaded sleeve 37 is in threaded connection with the wall of the threaded rod 35, one side of the threaded sleeve 37 close to the second sliding chute 26 is fixedly connected with a sliding rod 38, one side of the sliding rod 38 close to the second sliding chute 26 extends into the second sliding chute 26 and is connected in the second sliding chute 26 in a sliding manner, the upper end of the threaded sleeve 37 is fixedly connected with a supporting rod 39, the upper end of the supporting rod 39 penetrates through the mounting opening 27 and extends out of the mounting box 24 and is fixedly connected with a second clamping plate 310, and one side of the first rotating rod 31 far away from the first bevel gear 32 is fixedly connected with a first gear 311.

The driving mechanism 4 comprises a driving plate 41, the driving plate 41 is fixedly connected to the outer side wall of the upper end of the mounting frame 21 close to the first mounting hole 22, the lower surface of the driving plate 41 is fixedly connected with a driving motor 42, the output end of the driving motor 42 is fixedly connected with a fourth bevel gear 43, a driving rod 44 is rotatably connected in the first mounting hole 22 at the lower end of the fourth bevel gear 43 through a bearing, a fifth bevel gear 45 is fixedly connected to a side wall of the driving rod 44 close to the fourth bevel gear 43, the fifth bevel gear 45 is engaged and connected to the lower end of the fourth bevel gear 43, one side of the driving rod 44 far away from the fifth bevel gear 45 penetrates through the first mounting hole 22 and extends into the mounting frame 21 and is fixedly sleeved with a first driving wheel 46, one side of the driving rod 44 close to the first driving wheel 46 is fixedly connected with a second gear 47, the second gear 47 is engaged and connected to the first gear 311, the fourth bevel gear 43 is driven to rotate conveniently by the driving plate 41 and the driving motor 42, so that the first driving wheel 46 and the second gear 47 are driven to rotate under the action of the fifth bevel gear 45 and the driving rod 44, and the clamping mechanism 3 is driven conveniently.

The transmission mechanism 5 comprises a transmission rod 51, the transmission rod 51 is rotatably connected with the inner side wall of the upper end of the mounting frame 21 on one side far away from the first mounting hole 22 through a bearing, a second transmission wheel 52 is fixedly sleeved on the corresponding position of the rod wall of the transmission rod 51 and the first transmission wheel 46, the second transmission wheel 52 and the first transmission wheel 46 are jointly in transmission connection with a belt 53, and a sixth bevel gear 54 is fixedly connected on one side of the transmission rod 51 far away from the second transmission wheel 52, so that the transmission rod 51 and the sixth bevel gear 54 are driven to rotate through the second transmission wheel 52 and the belt 53, and the seventh bevel gear 56 is driven conveniently.

Be close to the mounting bracket 21 top inside wall on one side of sixth conical gear 54 and rotate through the bearing and be connected with a dwang 55, the pole wall of the corresponding position of dwang 55 and sixth conical gear 54 all fixedly cup joints a seventh conical gear 56, seventh conical gear 56 meshing is connected on sixth conical gear 54, third gear 57 of pole wall fixedly connected with under the dwang 55, be favorable to driving seventh conical gear 56 through seventh conical gear 56, thereby can drive dwang 55 and third gear 57 and rotate, be convenient for drive towards milling machine 6.

Towards milling mechanism 6 and including a slide 61, slide 61 sliding connection is in first spout 23, and a rack plate 62 of slide 61 lower extreme fixedly connected with, and the meshing of rack plate 62 is connected on third gear 57, is favorable to conveniently driving rack plate 62 through first spout 23 and slide 61 and removes to can drive telescopic cylinder 63 and remove adjusting position.

The lower surface of the rack plate 62 is fixedly connected with a telescopic cylinder 63, the output end of the telescopic cylinder 63 is movably connected with a piston rod 64, the lower end of the piston rod 64 is fixedly connected with a movable plate 65, two sensors 66 are fixedly mounted on two sides of the lower surface of the movable plate 65, and a milling cutter 67 is fixedly connected to the center of the lower end of the movable plate 65, so that the movable plate 65 can be conveniently driven to descend through the telescopic cylinder 63 and the piston rod 64, and a machined part can be rapidly machined by the milling cutter 67.

The power-off mechanism 7 comprises a power supply 71, the power supply 71 is fixedly connected to the upper surface of the driving plate 41, the power supply 71 is electrically connected with the two sensors 66, the power supply 71 is electrically connected with the driving motor 42 and the telescopic cylinder 63, a mounting plate 72 is fixedly connected to the lower end of one side of the power supply 71, which is far away from the mounting frame 21, a power-off groove 73 is formed in one side of the mounting plate 72, a first wire core 74 is fixedly mounted on one side of the power-off groove 73, which is close to the power supply 71, the first wire core 74 is electrically connected with the power supply 71, a second wire core 75 is fixedly mounted on one side of the power-off groove 73, which is far away from the power supply 71, the lower end of the second wire core 75 extends out of the mounting plate 72 and is fixedly mounted on the driving motor 42, a stepping motor 76 is fixedly connected to the outer side wall of the power supply 71, which is located at the upper end of the mounting plate 72, an output end of the stepping motor 77 is fixedly connected with a power-off rod 78, the lower extreme of outage board 78 extends to outage groove 73 in and connecting wire core 79 of fixedly connected with, and connecting wire core 79 both sides and first sinle silk 74 and second sinle silk 75 offset, are favorable to driving step motor 76 through power 71 to it is harsh, fast outage to connect sinle silk 79 from first sinle silk 74 and second sinle silk 75 under the effect of outage pole 77 and outage board 78.

the first step is as follows: firstly, a workpiece is placed on the upper surface of the installation box 24, then the driving motor 42 is started, the output end of the driving motor 42 can be meshed with the fourth bevel gear 43, the fifth bevel gear 45, the driving rod 44 and the second gear 47 to drive the first gear 311 and the first rotating rod 31, so that the threaded rod 35 can be driven to rotate by the first bevel gear 32, the second bevel gear 34 and the third bevel gear 36, the threaded sleeve 37 and the second clamping plate 310 can be driven to move under the sliding limiting action of the second sliding groove 26 and the sliding rod 38, and the first clamping plate 28 is matched to conveniently, stably and quickly clamp a processing block;

the second step is that: the second transmission wheel 52, the transmission rod 51 and the sixth bevel gear 54 are driven to rotate by the first transmission wheel 46 and the belt 53, so that the rotating rod 55 and the third gear 57 are driven to rotate under the action of the seventh bevel gear 56, the rack plate 62 can be driven to move under the action of the first chute 23 and the sliding plate 61, the position of the milling cutter 67 can be conveniently adjusted, and then the milling cutter 67 is driven to descend by the telescopic cylinder 63 and the piston rod 64, so that the rapid machining is facilitated;

the third step: when the two sensors 66 sense that the milling cutter 67 works abnormally, the stepping motor 76 is started through the power supply 71, the stepping motor 76 can separate the connecting wire core 79 from the first wire core 74 and the second wire core 75 through the power-off rod 77 and the power-off plate 78, and therefore the driving motor 42 can be powered off, and danger is avoided.

Specifically, when the invention is used, a processing block to be processed is firstly placed at the upper end of the installation box 24, then one side of the processing block is abutted against the first clamping plate 28, the driving motor 42 is started, the output end of the driving motor 42 drives the fourth bevel gear 43 to rotate, the fourth bevel gear 43 is meshed to drive the fifth bevel gear 45 to rotate, the fifth bevel gear 45 drives the driving rod 44 to rotate through the first installation hole 22, the driving rod 44 synchronously drives the first transmission wheel 46 and the second gear 47 to rotate, at this time, the second gear 47 is meshed to drive the first gear 311 to rotate, the first gear 311 drives the first rotating rod 31 to rotate through the second installation hole 25, the first rotating rod 31 drives the first bevel gear 32 to rotate, the first bevel gear 32 drives the second bevel gear 34 to rotate through the bearing and the second rotating rod 33, the second bevel gear 34 is meshed to drive the third bevel gear 36 to rotate, the third bevel gear 36 drives the threaded rod 35 to rotate through the bearing, the threaded rod 35 synchronously drives the threaded sleeve 37, the threaded sleeve 37 can move on the rod wall of the threaded rod 35 through the sliding limiting effect of the sliding rod 38 and the second sliding groove 26, at the moment, the upper end of the threaded sleeve 37 drives the second clamping plate 310 to move through the supporting rod 39 and the mounting opening 27, the second clamping plate 310 is matched with the first clamping plate 28 to stably clamp a processing block, at the moment, the first transmission wheel 46 drives the second transmission wheel 52 to rotate through the belt 53, the second transmission wheel 52 drives the transmission rod 51 to rotate through the bearing, the transmission rod 51 drives the sixth conical gear 54 to rotate, the sixth conical gear 54 is meshed to drive the seventh conical gear 56 to rotate, the seventh conical gear 56 drives the rotating rod 55 to rotate through the bearing, the rod wall at the lower end of the rotating rod 55 drives the third gear 57 to rotate, the third gear 57 is meshed to the ceiling rack plate 62, the rack plate 62 can stably move through the sliding limiting effect of the sliding plate 61 and the first sliding groove 23, rack board 62 moves suitable position through telescopic cylinder 63 and movable plate 65 ceiling milling cutter 67, centre gripping processing piece can be stabilized to second splint 310 and first splint 28 this moment, then start telescopic cylinder 63, telescopic cylinder 63 can drive milling cutter 67 through piston rod 64 and movable plate 65 and wash the milling to the processing piece fast, the sensor 66 of movable plate 65 both sides senses milling cutter 67 work wrong back, two sensors 66 pass through power 71 and start step motor 76, step motor 76 can be connected sinle silk 79 from first sinle silk 74 through disconnected pole 77 and outage board 78, second sinle silk 75 and outage groove 73 remove the department, driving motor 42 and telescopic cylinder 63 can lose electric power this moment, thereby can cut off the power supply fast, increase the processing security.

The invention has the beneficial effects that:

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and the embodiments and descriptions given above are only illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The intelligent numerical control milling machine with the power-off structure is characterized by comprising a bottom plate (1), wherein the upper end of the bottom plate (1) is fixedly connected with an installation mechanism (2), the interior of the installation mechanism (2) is rotatably connected with a clamping mechanism (3), the exterior of one side of the installation mechanism (2) is fixedly connected with a driving mechanism (4), the driving mechanism (4) is meshed and connected with the clamping mechanism (3), the inner side wall of one side, far away from the clamping mechanism (3), of the installation mechanism (2) is rotatably connected with a transmission mechanism (5), one side, close to the clamping mechanism (3), of the transmission mechanism (5) is meshed and connected with a punching and milling mechanism (6), and the upper end of the driving mechanism (4) is fixedly connected with a power-off mechanism (7); the mounting mechanism (2) comprises a mounting rack (21), the mounting rack (21) is fixedly connected with the upper surfaces of two sides of the bottom plate (1), a first mounting hole (22) is formed in the side wall of one side of the mounting rack (21) close to the lower end in a penetrating manner, and one side of the top end of the mounting rack (21) far away from the first mounting hole (22) is provided with a first sliding chute (23), and the upper surface of the bottom plate (1) positioned in the middle of the mounting rack (21) is fixedly connected with a mounting box (24), a second mounting hole (25) is arranged on one side of the mounting box (24) close to the first mounting hole (22) in a penetrating way, a second sliding groove (26) is arranged on one side of the installation box (24), an installation opening (27) is arranged on the wall of the installation box (24) at the upper end of the second sliding groove (26) in a penetrating way, a first clamping plate (28) is fixedly connected to the upper surface of one side, far away from the mounting opening (27), of the mounting box (24); the clamping mechanism (3) comprises a first rotating rod (31), the first rotating rod (31) is connected into the second mounting hole (25) in a rotating mode through a bearing, a first bevel gear (32) is fixedly connected to one side, far away from the first mounting hole (22), of the first rotating rod (31), the inner box wall at the bottom end of the mounting box (24) close to one side of the first bevel gear (32) is connected with a second rotating rod (33) in a rotating mode through a bearing, a second bevel gear (34) is fixedly connected to the upper end of the second rotating rod (33), the second bevel gear (34) is meshed and connected to the lower end of the first bevel gear (32), the inner box wall of the mounting box (24) far away from one side of the first bevel gear (32) is connected with a threaded rod (35) in a rotating mode through a bearing, a third bevel gear (36) is fixedly connected to one side, near the second bevel gear (34), of the threaded rod (35), just third bevel gear (36) meshing connection is in the one side of keeping away from first bevel gear (32), threaded rod (35) pole wall threaded connection has a thread bush (37), one side fixedly connected with slide bar (38) that thread bush (37) are close to second spout (26), slide bar (38) are close to one side of second spout (26) and extend to in second spout (26) and sliding connection in second spout (26), a bracing piece (39) of thread bush (37) upper end fixedly connected with, bracing piece (39) upper end is passed installing port (27) and is extended to install bin (24) outer and a fixedly connected with second splint (310), one side fixedly connected with first gear (311) of first bevel gear (32) are kept away from in first bull stick (31).

2. The intelligent numerical control milling machine with the power-off structure as claimed in claim 1, wherein: the driving mechanism (4) comprises a driving plate (41), the driving plate (41) is fixedly connected to the outer side wall of the upper end of the mounting frame (21) close to the first mounting hole (22), the lower surface of the driving plate (41) is fixedly connected with a driving motor (42), the output end of the driving motor (42) is fixedly connected with a fourth bevel gear (43), the driving rod (44) is positioned in the first mounting hole (22) at the lower end of the fourth bevel gear (43) and is rotatably connected with a driving rod through a bearing, a side rod wall of the driving rod (44) close to the fourth bevel gear (43) is fixedly connected with a fifth bevel gear (45), the fifth bevel gear (45) is meshed with the lower end of the fourth bevel gear (43), one side, far away from the fifth bevel gear (45), of the driving rod (44) penetrates through the first mounting hole (22) and extends into the mounting frame (21) and is fixedly sleeved with a first driving wheel (46), and one side of the driving rod (44) close to the first transmission wheel (46) is fixedly connected with a second gear (47), and the second gear (47) is meshed and connected with the first gear (311).

3. The intelligent numerical control milling machine with the power-off structure as claimed in claim 1, wherein: drive mechanism (5) include a transfer line (51), transfer line (51) are connected through the bearing and are located mounting bracket (21) upper end inside wall of keeping away from first mounting hole (22) one side, just transfer line (51) pole wall and first drive wheel (46) corresponding rigidity cup joints a second drive wheel (52), second drive wheel (52) and first drive wheel (46) are transmission connection jointly has a belt (53), one side fixedly connected with sixth conical gear (54) of second drive wheel (52) are kept away from in transfer line (51).

4. The intelligent numerical control milling machine with the power-off structure as claimed in claim 3, wherein: be close to mounting bracket (21) top inside wall on one side of sixth conical gear (54) is connected with a dwang (55) through the bearing rotation, the pole wall of dwang (55) and sixth conical gear (54) corresponding position all fixedly cup joints a seventh conical gear (56), seventh conical gear (56) meshing is connected on sixth conical gear (54), third gear (57) of pole wall fixedly connected with under dwang (55).

5. The intelligent numerical control milling machine with the power-off structure as claimed in claim 1, wherein: towards milling machine structure (6) and including a slide (61), slide (61) sliding connection is in first spout (23), just slide (61) lower extreme fixedly connected with a rack plate (62), rack plate (62) meshing is connected on third gear (57).

6. The intelligent numerical control milling machine with the power-off structure as claimed in claim 5, wherein: rack plate (62) lower surface fixedly connected with one telescopic cylinder (63), telescopic cylinder (63) output end swing joint has a piston rod (64), a movable plate (65) of piston rod (64) lower extreme fixedly connected with, movable plate (65) lower surface both sides fixed mounting has two sensors (66), just a milling cutter (67) of fixedly connected with is located at movable plate (65) lower extreme center.

7. The intelligent numerical control milling machine with the power-off structure as claimed in claim 1, wherein: outage mechanism (7) includes a power (71), power (71) fixed connection is on drive plate (41) upper surface, just power (71) and two sensor (66) electric connection, power (71) and driving motor (42) and telescopic cylinder (63) electric connection, one side lower extreme fixedly connected with mounting panel (72) of mounting bracket (21) are kept away from in power (71), a outage groove (73) has been seted up to mounting panel (72) one side, one side fixed mounting that outage groove (73) are close to power (71) has a first sinle silk (74), just first sinle silk (74) and power (71) electric connection, one side fixed mounting that outage groove (73) kept away from power (71) has a second sinle silk (75), second sinle silk (75) lower extreme extends to mounting panel (72) outer and fixed mounting on driving motor (42), be located step motor (76) of upper end power (71) lateral wall fixedly connected with of mounting panel (72), step motor (76) output end fixedly connected with is a disconnected pole (77), disconnected pole (77) keep away from one side fixedly connected with outage board (78) of step motor (76), outage board (78) lower extreme extends to outage groove (73) in and fixedly connected with one connects sinle silk (79), connect sinle silk (79) both sides and first sinle silk (74) and second sinle silk (75) counterbalance.

8. A use method of the intelligent numerically controlled milling machine with the power-off structure according to any one of claims 1 to 7, characterized in that: the method comprises the following steps:

the first step is as follows: firstly, a workpiece is placed on the upper surface of the mounting box (24), then the driving motor (42) is started, the output end of the driving motor (42) can be meshed with the fourth bevel gear (43), the fifth bevel gear (45), the driving rod (44) and the second gear (47) to drive the first gear (311) and the first rotating rod (31), so that the threaded rod (35) can be driven to rotate by the first bevel gear (32), the second bevel gear (34) and the third bevel gear (36), the threaded sleeve (37) and the second clamping plate (310) can be driven to move under the sliding limiting effect of the second sliding chute (26) and the sliding rod (38), and the first clamping plate (28) is matched to conveniently, stably and quickly clamp a processing block;

the second step is that: the second transmission wheel (52), the transmission rod (51) and the sixth bevel gear (54) are driven to rotate through the first transmission wheel (46) and the belt (53), so that the rotation rod (55) and the third gear (57) are driven to rotate under the action of the seventh bevel gear (56), the rack plate (62) can be driven to move under the action of the first sliding chute (23) and the sliding plate (61), the position of the milling cutter (67) is conveniently adjusted, and then the milling cutter (67) is driven to descend through the telescopic cylinder (63) and the piston rod (64), so that rapid machining is facilitated;

the third step: when two sensors (66) sense milling cutter (67) abnormal work, can start step motor (76) through power (71), step motor (76) can leave connection sinle silk (79) from first sinle silk (74) and second sinle silk (75) in through disconnected pole (77) and outage board (78) to can cut off the power supply with driving motor (42), avoid taking place danger.