CN117400123A - Device for numerical control machining center - Google Patents

Abstract

The invention discloses a device for a numerical control machining center, and relates to the technical field of numerical control machining. The invention comprises a processing area main body, wherein one end of the processing area main body is provided with a conveying assembly, and the top of the conveying assembly, which is close to the processing area main body, is provided with a clamping processing assembly. According to the invention, through the arrangement of the conveying assembly, automatic feeding operation can be performed before processing, automatic placement of the polishing materials is convenient for feeding, and further the working efficiency of the data processing center is improved.

Description

Device for numerical control machining center

Technical Field

The invention relates to the technical field of numerical control machining, in particular to a device for a numerical control machining center.

Background

The numerical control machining center is a high-efficiency automatic machine tool which is composed of mechanical equipment and a numerical control system and is suitable for machining complex parts, and in the machining process of the numerical control machining center, a large amount of powdery or filiform metal waste is generated when the tool machines the die.

Reference is made to the issued patent number "CN109264396a" discloses a numerical control automatic feeding machine in which: when the device is used, the working efficiency is greatly improved, meanwhile, the manual feeding and discharging operation is not needed, multiple devices can be controlled by one person, and the working efficiency is greatly improved.

In the process of implementing the patent, the applicant finds that the following technical problems exist in the patent:

because the loading attachment who sets for in this patent can not carry out the preliminary treatment operation to the surface of polishing abrasive material, and then when polishing the sword and contacting the material of polishing that there is impurity on the surface, can arouse the corruption of cutter, can influence the processing effect of product simultaneously, for this reason, this application provides a device for numerical control machining center, for solving the technical problem who mentions in the above-mentioned patent, provides a new technical scheme. .

Disclosure of Invention

Based on the above, a device for a numerical control machining center is provided, which is used for solving the following technical problems in the background art: because the loading attachment who sets for in this patent can not carry out the preliminary treatment operation to the surface of polishing abrasive material, and then when polishing the sword and contacting the material of polishing that there is impurity on the surface, can arouse the corruption of cutter, can influence the processing effect of product simultaneously.

The invention adopts the following technical scheme:

the device for the numerical control machining center specifically comprises a machining area main body, wherein a conveying assembly is arranged at one end of the machining area main body, and a clamping processing assembly is arranged at the top of the conveying assembly, which is close to the machining area main body;

the conveying assembly comprises a fixed box, a conveying placing box and a conveying belt, wherein one end of the processing area main body is fixedly connected with the fixed box, the fixed box is far away from one end of the processing area main body, the conveying placing box is arranged at the top of the conveying placing box in a concave mode, the conveying placing box is far away from one end of the fixed box, the conveying belt is close to the end portion of the conveying placing box, and the groove position of the top of the conveying placing box corresponds to the groove position of the top of the conveying placing box.

Further, the conveying assembly further comprises a rotating plate and a first single-head motor, a first reserved groove is formed in the inner side of the middle of the conveying placing box, sliding grooves are formed in the inner sides of the two sides of the conveying placing box, the two sliding grooves are communicated with the first reserved groove, the rotating plate is arranged in the inner side of the first reserved groove, the first single-head motor is installed at the bottom of the conveying placing box, and the output end of the first single-head motor penetrates through the bottom of the conveying placing box and extends to the inner side of the first reserved groove and is fixedly connected with the rotating plate.

Further, the conveying subassembly still includes drive plate, slip box, promotes displacement piece and spring, two the equal sliding connection in slip groove inboard has the drive plate, two the drive plate is L type setting, and two the drive plate bottom all extends to first reservation inslot side and with the rotation board both sides are swivelling joint cooperation, two the equal fixedly connected with slip box in drive plate top, two the slip box all with the transport is placed the case and is sliding connection cooperation, and extends to the transport is placed case recess inboard, two the equal sliding connection in slip box inboard has the promotion displacement piece, and two promote the displacement piece position and be the symmetry setting, two the slip box inboard all is provided with the spring, and two promote the displacement piece all through two the spring is sliding connection setting with two the slip box.

Further, the conveying subassembly still includes double-end motor, drive pole, first dwang, second dwang and rotates the concave plate, the conveying is placed the case inboard and is seted up the second and reserve the groove, just the second is reserved the groove and is located first reservation groove top, the second is reserved the inslot and is installed double-end motor, the equal fixedly connected with drive pole in double-end motor both ends, two support grooves have been seted up to conveying is placed case top recess, two the inboard equal swivelling joint of support groove has first dwang, two the equal swivelling joint of first dwang other end has the second dwang, two the drive pole is kept away from the one end of double-end motor all with two first dwang and two second dwang hookup location is the swivelling joint setting, two the second dwang is kept away from the equal swivelling joint of one end of first dwang has the concave plate, two the concave plate all with two support groove top is swivelling joint setting, and two the concave plate is the symmetry setting.

Further, the clamping processing assembly comprises six mechanical arms, fixed cylindrical arms, first connecting strips and a fixed disc, wherein the six mechanical arms are installed on one side of the top of the fixed box, the six mechanical arms are far away from the fixed cylindrical arms fixedly connected with the end parts of the fixed box, four first connecting strips are fixedly connected with the bottom of the fixed cylindrical arms, the four first connecting strips are arranged in a circumferential array, and the four first connecting strips are far away from the fixed cylindrical arms, and the fixed disc is fixedly connected with the end parts of the fixed cylindrical arms.

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

the device for the numerical control machining center can automatically feed before machining, automatically place grinding materials for feeding, and further improve the working efficiency of the data machining center.

The device for the numerical control machining center can clean and remove oil on the surface of the grinding material, further protect the grinding tool, prevent the tool from being corroded due to contact with impurities on the surface of the material, and further prolong the service life of the data machining center.

Drawings

In order to more clearly illustrate the solution of the present invention, a brief description will be given below of the drawings required for the description of the embodiments, it being obvious that the drawings in the following description are some embodiments of the present invention, and that other drawings may be obtained from these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of the overall structure of a device for a numerical control machining center;

fig. 2 is a schematic structural diagram of a device conveying assembly for a numerical control machining center provided by the invention;

FIG. 3 is a schematic diagram of a device transfer box for a numerical control machining center;

fig. 4 is a schematic structural view of a double-headed motor for a numerical control machining center;

FIG. 5 is a schematic diagram of a device clamping processing assembly for a numerical control machining center;

FIG. 6 is a schematic view of a device for fixing a cylindrical arm for a numerical control machining center;

FIG. 7 is a schematic structural view of a device buckling plate for a numerical control machining center;

FIG. 8 is a schematic diagram of a device pump drive for a numerical control machining center;

FIG. 9 is a schematic diagram of a device for collecting waste materials in a numerical control machining center;

FIG. 10 is a schematic diagram of the structure of an air suction collection assembly of the device for the numerical control machining center;

FIG. 11 is a schematic structural view of a device fixing tooth for a numerical control machining center;

Fig. 12 is a schematic structural view of a device waste collection box for a numerical control machining center provided by the invention;

FIG. 13 is a schematic view of a device for a numerically controlled machining center of the present invention;

fig. 14 is a schematic structural view of a device fixing connecting rod for a numerical control machining center;

FIG. 15 is a schematic view of a liquid collecting assembly of a device for a numerical control machining center according to the present invention;

fig. 16 is a schematic structural diagram of a solid-liquid separation assembly of a device for a numerical control machining center.

In the drawings, the list of components represented by the various numbers is as follows:

1. a machining region main body; 2. a waste collection device; 3. a waste collection box; 4. a universal wheel; 5. a suction collection assembly; 6. a waste screening assembly; 7. a liquid collection assembly; 8. a solid-liquid separation assembly; 9. a fixed box; 10. an air suction motor; 11. a discharge pipe; 12. an air suction head; 13. a fixed tooth; 14. moving the teeth; 15. fixing the connecting plate; 16. a first electric push cylinder; 17. a first collection box; 18. a partition plate; 19. a first filter plate; 20. a first sliding groove; 21. an I-shaped sliding plate; 22. a second electric push cylinder; 23. fixing the connecting rod; 24. a first connecting vertical rod; 25. a second filter plate; 26. the second connecting vertical rod; 27. a first fixing plate; 28. a third electric push cylinder; 29. a second fixing plate; 30. a slide bar; 31. a water draining square tube; 32. a protection box; 33. a rotating motor; 34. a rotating rod; 35. stirring the arc plate; 36. a closing plate; 37. a second collection box; 38. a third collection box; 39. a second chute; 40. a third chute; 41. a driving motor; 42. thirdly, connecting a vertical rod; 43. a third filter plate; 44. fixing the rotating column; 45. a transfer assembly; 46. a clamping processing assembly; 47. a fixed box; 48. conveying the placement box; 49. a conveyor belt; 50. a rotating plate; 51. a first single-head motor; 52. a drive plate; 53. a slide box; 54. pushing the displacement block; 55. a spring; 56. a double-ended motor; 57. a drive rod; 58. a first rotating lever; 59. a second rotating lever; 60. rotating the concave plate; 61. a six-axis mechanical arm; 62. fixing the cylindrical arm; 63. a first connecting bar; 64. a fixed plate; 65. a first telescopic rod; 66. a displacement plate; 67. a grabbing clamp; 68. connecting a rotating rod; 69. rotating the ring arm; 70. a second connecting bar; 71. a buckling plate; 72. a second single-head motor; 73. a liquid outlet pipe; 74. polishing the column; 75. driving liquid suction; 76. a first fixed ring plate; 77. a second fixed ring plate; 78. a rotating disc; 79. connecting a rotating column; 80. a third single-head motor; 81. a sliding placement seat; 82. a second telescopic rod; 83. and lifting the plate.

Detailed Description

In order that those skilled in the art will better understand the present invention, a technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in which it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present invention without making any inventive effort, shall fall within the scope of the present invention.

As in the background art, since the feeding device set in the patent cannot perform pretreatment operation on the surface of the polishing material, when the polishing blade contacts the polishing material with impurities on the surface, corrosion of the blade is caused, and the processing effect of the product is affected.

In order to solve the technical problem, the invention provides a device for a numerical control machining center, which can automatically feed before machining, automatically place grinding materials for feeding, and further improve the working efficiency of the data machining center.

Referring to fig. 1 to fig. 4, a device for a numerical control machining center specifically includes a machining area main body 1, a conveying assembly 45 is installed at one end of the machining area main body 1, and a clamping processing assembly 46 is installed at the top of the conveying assembly 45 near the machining area main body 1;

The conveying assembly 45 comprises a fixed box 47, a conveying placing box 48 and a conveying belt 49, the fixed box 47 is fixedly connected to one end of the processing area main body 1, the conveying placing box 48 is fixedly connected to one end, far away from the processing area main body 1, of the fixed box 47, the top of the conveying placing box 48 is arranged in a concave mode, the conveying placing box 48 is fixedly connected with the conveying belt 49 at one end, far away from the fixed box 47, of the conveying placing box 48, and the end, close to the conveying placing box 48, of the conveying belt 49 corresponds to the groove position of the top of the conveying placing box 48.

In order to make the person skilled in the art better understand the solution of the present invention, the technical solution of the embodiment of the present invention will be clearly and completely described below with reference to the accompanying drawings.

Example 1:

referring to fig. 1, a device for a numerical control machining center includes a machining area body 1, a conveying assembly 45 is installed at one end of the machining area body 1, and a clamping processing assembly 46 is installed at the top of the conveying assembly 45 near the machining area body 1.

The machining area main body 1 is used for machining and manufacturing mechanical parts;

the conveying component 45 plays a role in automatically conveying and placing the polishing materials;

the clamping processing assembly 46 plays a role in clamping the polishing materials after being placed, and meanwhile, through the arrangement of the clamping processing assembly 46, the processing area main body 1 can be rapidly fed, and therefore the working efficiency of the processing area main body 1 is improved.

Example 2:

the embodiment 2 is used for further disclosing a specific structure of the conveying assembly 45 on the premise of the above embodiment, and through the structural cooperation of the conveying assembly 45 and the above embodiment, automatic feeding operation can be performed before processing, automatic placement of polishing materials is performed for facilitating feeding, and further working efficiency of a data processing center is improved.

For a further optimization of the device for a numerical control machining center provided in embodiment 1, specifically, as shown in fig. 2-4, the conveying assembly 45 includes a fixing box 47, a conveying placing box 48 and a conveying belt 49, one end of the machining area main body 1 is fixedly connected with the fixing box 47, one end of the fixing box 47 far away from the machining area main body 1 is fixedly connected with the conveying placing box 48, the top of the conveying placing box 48 is arranged in a concave mode, one end of the conveying placing box 48 far away from the fixing box 47 is fixedly connected with the conveying belt 49, and the end, close to the conveying placing box 48, of the conveying belt 49 corresponds to the groove position at the top of the conveying placing box 48.

The conveying assembly 45 further comprises a rotating plate 50 and a first single-head motor 51, a first reserved groove is formed in the inner side of the middle of the conveying placing box 48, sliding grooves are formed in the two sides, located on the first reserved groove, of the inner sides of the two sides of the conveying placing box 48, the two sliding grooves are communicated with the first reserved groove, the rotating plate 50 is arranged on the inner side of the first reserved groove, the first single-head motor 51 is arranged at the bottom of the conveying placing box 48, the output end of the first single-head motor 51 penetrates through the bottom of the conveying placing box 48 and extends to the inner side of the first reserved groove, and the first single-head motor is fixedly connected with the rotating plate 50.

The conveying assembly 45 further comprises a transmission plate 52, sliding boxes 53, pushing displacement blocks 54 and springs 55, wherein the inner sides of the two sliding grooves are all connected with the transmission plate 52 in a sliding mode, the two transmission plates 52 are arranged in an L-shaped mode, the bottoms of the two transmission plates 52 are all extended to the inner sides of the first reserved grooves and are matched with the two sides of the rotating plate 50 in a rotating mode, the tops of the two transmission plates 52 are all fixedly connected with the sliding boxes 53, the two sliding boxes 53 are matched with the conveying placing box 48 in a sliding mode and are extended to the inner sides of the grooves of the conveying placing box 48, the pushing displacement blocks 54 are all connected with the inner sides of the two sliding boxes 53 in a sliding mode, the positions of the two pushing displacement blocks 54 are symmetrically arranged, the springs 55 are arranged on the inner sides of the two sliding boxes 53, and the two pushing displacement blocks 54 are all arranged in a sliding mode through the two springs 55 and the two sliding boxes 53.

The conveying assembly 45 further comprises a double-headed motor 56, a driving rod 57, a first rotating rod 58, a second rotating rod 59 and a rotating concave plate 60, a second reserved groove is formed in the inner side of the conveying placing box 48 and located at the top of the first reserved groove, the double-headed motor 56 is mounted on the inner side of the second reserved groove, the driving rod 57 is fixedly connected to the two ends of the double-headed motor 56, two supporting grooves are formed in the groove at the top of the conveying placing box 48, the first rotating rod 58 is rotatably connected to the inner side of the two supporting grooves, the second rotating rod 59 is rotatably connected to the other ends of the two first rotating rods 58, one ends of the two driving rods 57, far away from the double-headed motor 56, are rotatably connected to the two first rotating rods 58 and the two second rotating rods 59, one ends of the two second rotating rods 59, far away from the first rotating rods 58, are rotatably connected to the rotating concave plate 60, the two rotating concave plates 60 are rotatably connected to the tops of the two supporting grooves, and the two rotating concave plates 60 are symmetrically arranged.

The polishing materials are conveyed through the arrangement of the conveying belt 49, when the polishing materials are conveyed to the groove at the top of the conveying and placing box 48 through the conveying belt 49, the first single-head motor 51 can be started, when the first single-head motor 51 rotates, the rotating plate 50 is driven to rotate at the inner side of the first reserved groove, and meanwhile, the transmission plates 52 at the two sides of the top of the rotating plate 50 are driven to synchronously approach, so that the two sliding boxes 53 at the top of the transmission plate 52 can approach each other, the polishing materials conveyed to the inner side of the groove of the conveying and placing box 48 can be clamped, and the polishing materials are driven to the middle of the groove of the conveying and placing box 48;

when the two sliding boxes 53 contact with the polishing materials, the polishing materials squeeze the two pushing displacement blocks 54, the two pushing displacement blocks 54 are squeezed to the inner sides of the two springs 55, and simultaneously, the polishing materials with different angles can be adjusted to be perpendicular to the main body 1 of the processing area when being conveyed to the inner sides of the grooves of the conveying and placing box 48 through the inclined planes of the two pushing displacement blocks 54;

meanwhile, by opening the double-headed motor 56, the driving rods 57 at the two ends of the double-headed motor 56 are driven to push away from the double-headed motor 56, so that the first rotating rod 58 and the second rotating rod 59 are opened by pushing of the driving rods 57, the rotating concave plate 60 is driven to rotate by moving of the second rotating rod 59, and the polishing materials perpendicular to the main body 1 of the processing area can be turned upwards when the two rotating concave plates 60 are simultaneously erected, and accordingly the polishing materials are in an upright state between the two rotating concave plates 60, so that the subsequent clamping of the polishing materials is facilitated, and the automation and convenience of feeding are improved.

Example 3:

the embodiment 3 is used for further disclosing the specific structure of the clamping processing assembly 46 on the premise of the embodiment, and through the cooperation of the clamping processing assembly 46 and the structure in the embodiment, the operations of cleaning and degreasing the surface of the polishing material can be achieved, the polishing tool is further protected, the phenomenon that the tool is corroded due to contact with impurities on the surface of the material is prevented, and therefore the service life of the data processing center is prolonged.

For further optimization of the device for the numerical control machining center provided in embodiment 1 and embodiment 2, specifically, as shown in fig. 5 to 8, the clamping processing assembly 46 includes a six-axis mechanical arm 61, a fixed cylindrical arm 62, a first connecting strip 63 and a fixed disk 64, the six-axis mechanical arm 61 is installed on one side of the top of the fixed box 47, the end portion of the six-axis mechanical arm 61 far away from the fixed box 47 is fixedly connected with the fixed cylindrical arm 62, the bottom of the fixed cylindrical arm 62 is fixedly connected with four first connecting strips 63, and the four first connecting strips 63 are arranged in a circumferential array, and the end portion of the four first connecting strips 63 far away from the fixed cylindrical arm 62 is fixedly connected with the fixed disk 64.

The clamping processing assembly 46 further comprises a first telescopic rod 65, a displacement disc 66, grabbing clamps 67 and connecting rotating rods 68, the bottom of the fixed cylindrical arm 62 is fixedly connected with the first telescopic rod 65, the first telescopic rod 65 penetrates through the inner side of the fixed disc 64 and extends to the bottom of the fixed disc 64, the end portion of the first telescopic rod 65 is fixedly connected with the displacement disc 66, the bottom of the fixed disc 64 is rotationally connected with the grabbing clamps 67, the grabbing clamps 67 are arranged in a circumferential array, the outer side of the displacement disc 66 is rotationally connected with the connecting rotating rods 68 in a circumferential array, and one end, far away from the displacement disc 66, of each connecting rotating rod 68 is matched with each grabbing clamp 67 in a rotating connection mode.

The clamping processing assembly 46 further comprises a rotating ring arm 69, a second connecting strip 70, buckling plates 71 and a second single-head motor 72, the rotating ring arm 69 is matched with the outer side of the fixed cylindrical arm 62 in a rotating mode, the end portion, far away from the fixed box 47, of the six-axis mechanical arm 61 is provided with the motor, the motor is located on the inner side of the fixed cylindrical arm 62 and drives the rotating ring arm 69 to rotate, the two sides of the rotating ring arm 69 are fixedly connected with the second connecting strip 70, buckling plates 71 are connected to the bottoms of the two second connecting strips 70 in a rotating mode, the second single-head motor 72 is arranged at the connecting positions of the two buckling plates 71 and the two second connecting strips 70, and the two second single-head motors 72 drive the two buckling plates 71 to rotate.

The clamping processing assembly 46 further comprises a liquid outlet pipe 73, polishing columns 74 and liquid pumping drives 75, wherein a plurality of liquid outlet pipes 73 are arranged on one adjacent sides of the two buckling plates 71, a plurality of liquid outlet holes are formed in the inner sides of the liquid outlet pipes 73, the polishing columns 74 are fixedly connected to the outer sides of the liquid outlet pipes 73, the liquid pumping drives 75 are fixedly connected to the sides, away from each other, of the two buckling plates 71, and the two liquid pumping drives 75 are communicated with the liquid outlet pipes 73 through a plurality of liquid conveying pipes on the inner sides of the two buckling plates 71.

The clamping processing assembly 46 further comprises a first fixed ring disc 76, a second fixed ring disc 77, rotating discs 78, connecting rotating columns 79 and a third single-head motor 80, wherein one side, close to the liquid suction driving device 75, of each of the two buckling plates 71 is fixedly connected with the first fixed ring disc 76 and the second fixed ring disc 77, the two first fixed ring discs 76 are located at the bottoms of the two liquid suction driving devices 75, the two second fixed ring discs 77 are located at the bottoms of the two first fixed ring discs 76, the rotating discs 78 are connected to the inner sides of the two first fixed ring discs 76 and the two second fixed ring discs 77 in a rotating mode, a plurality of circular grooves are formed in the inner sides of each rotating disc 78, connecting rotating columns 79 are arranged between the two rotating discs 78, two ends of each connecting rotating column 79 are fixedly connected with the two rotating discs 78, the bottoms of each of the two second fixed ring discs 77 are provided with the third single-head motor 80, and the output ends of each of the two third single-head motors 80 penetrate through the two second fixed ring discs 77 and are fixedly connected with the connecting rotating columns 79.

The clamping processing assembly 46 further comprises a sliding placing seat 81, a second telescopic rod 82 and a pulling plate 83, wherein a plurality of sliding placing seats 81 are connected to the inner sides of round grooves formed in the two bottom rotating discs 78 in a sliding mode, pulling grooves are formed in the outer sides of the sliding placing seats 81, driving grooves are formed in the outer sides of the two buckling plates 71, the driving grooves are formed between the two first fixed annular discs 76 and the two second fixed annular discs 77, the second telescopic rods 82 are fixedly connected to the inner sides of the two driving grooves, pulling plates 83 are fixedly connected to the bottoms of the two second telescopic rods 82, and the pulling plates 83 are in clearance fit with the pulling grooves of the sliding placing seats 81.

After the polishing material is adjusted to be in a vertical state, the six-axis mechanical arm 61 can be moved to the top of the polishing material by controlling the six-axis mechanical arm 61, and the end part of the six-axis mechanical arm 61, which is far away from the fixed box 47, is lowered to clamp the polishing material;

when the plurality of grabbing clamps 67 are moved to the outer side of the polishing material, the first telescopic rod 65 can be controlled to stretch out and draw back to drive the displacement disc 66 to move, and when the displacement disc 66 moves upwards, the plurality of connecting rotating rods 68 can be driven to synchronously move, so that the plurality of grabbing clamps 67 are driven to synchronously shrink and move through the arrangement of the plurality of connecting rotating rods 68, the effect of clamping the polishing material after being vertical is further achieved, and meanwhile, the polishing material can be driven to the inner side of the main body 1 of the processing area to carry out subsequent processing operation;

When the surface pretreatment of the polishing materials is needed, the two buckling plates 71 can be turned over by starting the two second single-head motors 72, so that the effect of the two buckling plates 71 on wrapping the clamped polishing materials is achieved, and a plurality of polishing columns 74 arranged on the inner sides of the buckling plates 71 are contacted with the surface of the polishing materials while the two buckling plates 71 wrap the polishing materials;

meanwhile, when the motor on the inner side of the fixed cylindrical arm 62 is started and the rotating ring arm 69 is driven to rotate, the rotating ring arm 69 can drive the two buckling plates 71 to synchronously rotate through the arrangement of the two second connecting strips 70, and at the moment, a plurality of polishing columns 74 on the inner side of the buckling plates 71 can carry out rotating friction on the polishing material surface, so that the operation of preprocessing the polishing material surface is realized;

before the polishing materials are pretreated, a plurality of treatment liquids with different effects can penetrate through the circular grooves of the rotating discs 78 and are placed on the inner sides of the sliding placing seats 81, the third single-head motor 80 is started to rotate, the rotating discs 78 are driven to synchronously rotate through the connecting rotating column 79, the corresponding treatment liquids can be rotated to the bottom of the liquid pumping drive 75 according to different impurities on the surface of the polishing materials, at the moment, the second telescopic rod 82 can be controlled to carry out upward telescopic movement to drive the lifting plate 83 at the bottom to carry out upward movement, and when the lifting plate 83 moves, the sliding placing seats 81 in clearance fit with the lifting plate 83 are driven to synchronously move, so that the treatment liquid bottles placed on the inner sides of the sliding placing seats 81 can be synchronously moved and are in plug fit with the liquid pumping drive 75;

At this time, the liquid pumping drive 75 is arranged, the treatment liquid bottle inserted at the bottom is extracted and conveyed to the inner sides of the liquid outlet pipes 73, and the liquid outlet holes are conveyed to the inside of the polishing column 74 through the arrangement of the liquid outlet holes formed in the liquid outlet pipes 73, so that the effect of wiping the surface of the polishing material is achieved, the impurity residues on the surface of the polishing material can be reduced, the polishing tool on the inner side of the main body 1 of the processing area is protected, the service life of the polishing tool is prolonged, and meanwhile, the working efficiency of the main body 1 of the processing area is improved.

Example 4:

the embodiment 4 is used for further disclosing the specific structure of the waste collection device 2 on the premise of the embodiment, and through the structural cooperation of the waste collection device 2 and the embodiment, the waste in the numerical control processing area can be collected and cleaned, and the collected waste is classified, so that the subsequent processing of the processing waste is more convenient, the waste with liquid in the numerical control processing area is cleaned, and the waste with cooling liquid is subjected to solid-liquid separation, so that the subsequent processing of the processing waste is more convenient.

Further optimizing a device for a numerical control machining center provided by the above embodiment, in particular, as shown in fig. 9 to 16,

The device comprises a processing area main body 1, wherein a waste collection device 2 is arranged at one end of the processing area main body 1;

the waste collection device 2 comprises a waste collection box 3, universal wheels 4, an air suction collection assembly 5, a waste screening assembly 6, a liquid collection assembly 7 and a solid-liquid separation assembly 8, wherein the waste collection box 3 is arranged at one end of a processing area main body 1, the universal wheels 4 are all installed at four corner positions at the bottom of the waste collection box 3, the air suction collection assembly 5 and the liquid collection assembly 7 are installed on the side wall, close to one end of the waste collection box 3, of the processing area main body 1, the air suction collection assembly 5 and the liquid collection assembly 7 penetrate through the side wall of the processing area main body 1 and extend to the outer side of the processing area main body 1, a first treatment tank and a second treatment tank are arranged on two sides of the inner side of the waste collection box 3, the waste screening assembly 6 is arranged on the inner side of the first treatment tank, the air suction collection assembly 5 and the waste collection box 3 are in plug-in fit and extend to the inner side of the waste screening assembly 6, the solid-liquid separation assembly 8 is arranged on the inner side of the second treatment tank, and the liquid collection assembly 7 and the waste collection box 3 are in plug-in fit and extend to the inner side of the solid-liquid separation assembly 8.

The machining area main body 1 is used for machining and manufacturing mechanical parts;

the waste collection device 2 is used for cleaning, collecting and classifying waste materials generated by part processing, so that a good processing environment is provided for the processing area main body 1, and the working efficiency of the processing area main body 1 is improved;

The waste collection box 3 is used for bearing the actions of the waste screening assembly 6 and the solid-liquid separation assembly 8, and meanwhile, through the arrangement of the universal wheels 4, the waste collection box 3 can be moved in position, so that after the waste collection box 3 collects the waste on the inner side of the processing area main body 1, the collected waste can be conveniently transported;

the suction collection assembly 5 is used for collecting normal waste, and can discharge the normal waste into the waste screening assembly 6 through the arrangement of the suction collection assembly 5, and classify and sort the normal waste through the arrangement of the waste screening assembly 6, so that the waste is convenient to post-treat;

the liquid collection assembly 7 is used for collecting the waste materials of the mixed cooling liquid, and meanwhile, through the arrangement of the liquid collection assembly 7, the waste materials mixed with the cooling liquid can be discharged into the solid-liquid separation assembly 8, and through the arrangement of the solid-liquid separation assembly 8, the waste materials of the mixed cooling liquid are treated and collected, and the working efficiency of the waste material collection device 2 is further improved.

Can place waste collection device 2 in the processing area main part 1 outside when using, the tip of processing area main part 1 outside of collection subassembly 5 and liquid collection subassembly 7 of breathing in can peg graft the cooperation with waste collection box 3 this moment, thereby according to the inboard circumstances of processing area main part 1, select to collect processing waste through collection subassembly 5 of breathing in or collect processing waste through liquid collection subassembly 7, after the processing of screening subassembly 6 and solid-liquid separation subassembly 8 of the waste, can select to remove waste collection box 3 as required whole, perhaps take out processing waste from waste collection box 3 inboard, so as to carry out the aftertreatment to processing waste, thereby enlarge waste collection device 2's application scope, promote waste collection device 2's work efficiency simultaneously.

The suction collection assembly 5 comprises a fixed box 9, a suction motor 10, a discharge pipe 11 and a suction head 12, wherein the fixed box 9 is fixedly connected with the side wall of the processing area main body 1, which is close to one end of the waste collection box 3, the suction motor 10 is arranged on the side wall of the processing area main body 1, which is close to one end of the waste collection box 3, the discharge pipe 11 is arranged on the inner side of the suction motor 10, the suction head 12 is fixedly connected with the end part, which is far away from the suction motor 10, of the discharge pipe 11, and the suction head 12 is in plug-in fit with the fixed box 9.

The air suction collection assembly 5 further comprises fixed teeth 13, movable teeth 14, a fixed connecting plate 15 and a first electric pushing cylinder 16, one end of the air suction head 12 is fixedly connected with the fixed teeth 13, the inner side of the fixed teeth 13 is slidably connected with the movable teeth 14, the bottom of the movable teeth 14 is fixedly connected with the fixed connecting plate 15, one end of the air suction head 12, which is close to the fixed teeth 13, is fixedly connected with the first electric pushing cylinder 16, the first electric pushing cylinder 16 is located at the bottom of the fixed connecting plate 15, and the output end of the first electric pushing cylinder 16 is fixedly connected with the bottom of the fixed connecting plate 15.

When the waste collection is required through the suction collection assembly 5, a worker can move the suction head 12 in a handheld manner, move the suction head 12 out of the inner side of the fixed box 9, and start the suction motor 10 to perform suction operation, and at the moment, the suction head 12 can be aligned with the waste accumulated in the inner side of the processing area main body 1 to absorb the waste and discharge the waste out of the inner side of the processing area main body 1 through the discharge pipe 11;

The first electric pushing cylinder 16 can be started under the condition that more processing waste is piled up to cause the work difficulty of the air suction collecting assembly 5, the fixed connecting plate 15 can be driven to reciprocate through the arrangement of the first electric pushing cylinder 16, at the moment, the fixed connecting plate 15 can drive the movable teeth 14 to synchronously reciprocate on the inner side of the fixed teeth 13, the effect that the piled up waste is loosened through frequent movement of the ends of the fixed teeth 13 and the movable teeth 14 can be achieved, so that the suction effect of the air suction head 12 can be improved, the residual processing waste on the inner side of the main body 1 of the processing area is reduced, and the working efficiency of the main body 1 of the processing area is further improved.

The waste screening assembly 6 comprises a first collecting box 17, a separation plate 18 and a first filter plate 19, the first collecting box 17 is slidably connected to the bottom of the first treatment tank, the separation plate 18 is fixedly connected to the middle of the inner side of the first collecting box 17, the first filter plate 19 is fixedly connected to the inner side of the first treatment tank, and the first filter plate 19 is located at one end close to the main body 1 of the processing area.

The waste screening assembly 6 further comprises a first sliding groove 20, an I-shaped sliding plate 21, a second electric pushing cylinder 22, fixed connecting rods 23, first connecting vertical rods 24 and second filter plates 25, wherein the first sliding groove 20 is fixedly connected to the two sides of the top of the first processing groove, the I-shaped sliding plates 21 are arranged on the adjacent sides of the two first sliding grooves 20 and are in sliding connection with the two first sliding grooves 20, the second electric pushing cylinder 22 is fixedly connected to the top of the first processing groove, the output end of the second electric pushing cylinder 22 is fixedly connected with the I-shaped sliding plates 21, the fixed connecting rods 23 are fixedly connected to the bottoms of the two sides of the I-shaped sliding plates 21, the two fixed connecting rods 23 are located at the bottoms of the two first sliding grooves 20, the bottoms of the two fixed connecting rods 23, which are far away from one end of the processing area main body 1, are fixedly connected with the first connecting vertical rods 24, the bottoms of the two first connecting vertical rods 24 are fixedly connected with the second filter plates 25 in a rotating mode, and the second filter plates 25 are located at the tops of the first filter plates 19 and are arranged in a staggered mode with the first filter plates 19.

The waste screening assembly 6 further comprises a second connecting vertical rod 26, a first fixing plate 27, a third electric pushing cylinder 28, a second fixing plate 29 and sliding rods 30, wherein the bottoms, close to one end of the main body 1 in the machining area, of the two fixing connecting rods 23 are all connected with the second connecting vertical rod 26 in a sliding manner, the bottoms of the two second connecting vertical rods 26 are all provided with the first fixing plate 27, the bottoms of the two second connecting vertical rods are all fixedly connected with the first fixing plate 27, the third electric pushing cylinder 28 is installed in the middle of the top of the first fixing plate 27, the output end of the third electric pushing cylinder 28 is fixedly connected with the second fixing plate 29, the bottoms of the two ends of the second fixing plate 29 are all fixedly connected with the sliding rods 30, the two sliding rods 30 penetrate through the two sides of the first fixing plate 27, and the bottoms of the two sliding rods 30 are all rotatably connected with the second filter plate 25.

After the processing waste material inside the processing area main body 1 is discharged to the inner side of the waste material screening assembly 6 through the discharge pipe 11, the processing waste material is accumulated at the top of the second filter plate 25, and then the second electric pushing cylinder 22 is started to reciprocate, so that the I-shaped sliding plate 21 is driven to reciprocate synchronously, and further the first connecting vertical rod 24 and the second connecting vertical rod 26 at the bottom of the fixed connecting rod 23 are driven to synchronously move through the fixed connection of the fixed connecting rod 23, so that the effect of driving the second filter plate 25 to reciprocate at the top of the first filter plate 19 is achieved;

By the staggered arrangement of the second filter plates 25 and the first filter plates 19, the effect of closing the filter holes of the second filter plates 25 and the first filter plates 19 can be achieved, and the filter holes can be opened while the second filter plates 25 reciprocate, so that powdery and filiform waste materials in the processing waste materials are separated, and the powdery processing waste materials flow into the first collecting box 17 through the first filter plates 19;

after separation, the third electric pushing cylinder 28 is controlled to push the second fixed plate 29 upwards, the sliding rods 30 on two sides are driven to slide upwards on two sides of the first fixed plate 27 while the second fixed plate 29 moves upwards, and meanwhile, the two sliding rods 30 drive one end of the second filter plate 25 to move upwards, so that the second filter plate 25 is inclined, and at the moment, the processing waste with larger top of the second filter plate 25 flows into the inner side of the first collecting box 17 through an inclined angle, so that the collecting effect is achieved;

at this time, the first collecting box 17 is arranged through the isolating plate 18, so that the powdery processing waste and the filiform processing waste can be classified, and the mixing of the processing waste is avoided, so that the processing waste is conveniently processed subsequently, and the working efficiency of waste processing is improved.

The liquid collection assembly 7 comprises a water draining square pipe 31, a protection box 32 and a rotating motor 33, wherein the side wall of the processing area main body 1, which is close to one end of the waste collection box 3, is fixedly connected with the water draining square pipe 31, the water draining square pipe 31 penetrates through the side wall of the processing area main body 1, the top of the water draining square pipe 31 is fixedly connected with the protection box 32, the protection box 32 is located inside the processing area main body 1, the rotating motor 33 is installed at the top of the water draining square pipe 31, and the rotating motor 33 is located inside the protection box 32.

The liquid collection assembly 7 further comprises a rotating rod 34, stirring arc plates 35 and a closing plate 36, the inner side of the square drainage tube 31 is rotationally connected with the rotating rod 34, the rotating rod 34 is located below the rotating motor 33, the output end of the rotating motor 33 penetrates through the top of the square drainage tube 31 and is fixedly connected with the rotating rod 34, four stirring arc plates 35 are fixedly connected to the outer side of the rotating rod 34 in a circumferential array mode, and the inner side of the square drainage tube 31, far away from one end of the protection box 32, is spliced with the closing plate 36.

When the cooling liquid is needed in the processing process, the processing waste at the bottom of the processing area is mixed with the cooling liquid, and when the processing waste mixed with the cooling liquid is collected, the sealing plate 36 can be pumped out of the inner side of the water draining square pipe 31, and at the moment, the liquid flows into the inner side of the solid-liquid separation assembly 8 through the arrangement of the water draining square pipe 31;

Simultaneously, the rotary motor 33 is controlled to drive the rotary rod 34 to rotate, so that the stirring arc plate 35 rotates on the inner side of the square drainage pipe 31 to stir the processing waste materials of the mixed cooling liquid, the phenomenon that the normal use of the square drainage pipe 31 is affected due to blockage caused by piled processing waste materials on the inner side of the square drainage pipe 31 can be avoided, meanwhile, the liquid can be guided through directional stirring, and the collection effect of the liquid waste materials is further improved.

The solid-liquid separation assembly 8 comprises a second collecting box 37, a third collecting box 38 and a second sliding groove 39, wherein the second collecting box 37 is inserted into the bottom of one side, close to the processing area main body 1, of the second processing groove, the third collecting box 38 is inserted into the bottom of one end, far away from the processing area main body 1, of the second processing groove, the second sliding grooves 39 are fixedly connected to two sides of the bottom of the inner side of the second processing groove, the two second sliding grooves 39 are located at the tops of the second collecting box 37 and the third collecting box 38, and limiting hooks are arranged at one ends, close to the third collecting box 38, of the two second sliding grooves 39.

The solid-liquid separation assembly 8 comprises a third chute 40, a driving motor 41, third connecting vertical rods 42, third filter plates 43 and fixed rotating columns 44, wherein the third chute 40 is fixedly connected to two sides of the inner side top of the second treatment tank, the driving motor 41 is slidably connected to the outer sides of the two third chutes 40, the third connecting vertical rods 42 are rotatably connected to the bottoms of the two driving motors 41, the third filter plates 43 are arranged at the bottoms of the two third connecting vertical rods 42, the two sides, close to one end of the processing area main body 1, of the third filter plates 43 are rotatably connected, the fixed rotating columns 44 are fixedly connected to two sides, far away from one end of the third connecting vertical rods 42, of the third filter plates 43, and the two fixed rotating columns 44 are in limit matching with limit hooks.

When the processing waste of the mixed cooling liquid flows into the inner side of the solid-liquid separation assembly 8 through the water drainage square pipe 31, the processing waste of the mixed cooling liquid is accumulated on the top of the third filter plate 43, solid-liquid separation is carried out through the arrangement of the third filter plate 43, and the separated cooling liquid flows into the inner side of the second collecting box 37 through the third filter plate 43 for collecting;

after a certain filtering time, the driving motor 41 is started to slide on the third chute 40, so that the third connecting vertical rod 42 at the bottom of the driving motor 41 is driven to synchronously move, and at the moment, the third filter plate 43 connected with the third connecting vertical rod 42 moves at the top of the second chute 39;

when the fixed rotating columns 44 on two sides of the third filter plate 43 move to the inner side of the limit hooks arranged at the end parts of the second sliding grooves 39, the third filter plate 43 stops moving, and at the moment, when the driving motor 41 continues to drive the third connecting vertical rods 42 to move, the third filter plate 43 is rotated and lifted by taking the fixed rotating columns 44 as the axes, so that the effect of tilting the third filter plate 43 is achieved, and then the processing waste materials after solid-liquid separation at the top of the third filter plate 43 are discharged to the inner side of the third collecting box 38 for collection;

Through the work of solid-liquid separation, can carry out further categorised of refining to the processing waste material that processing area main part 1 produced, and then promote the work efficiency to the processing waste material follow-up treatment.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (10)

1. The device for the numerical control machining center comprises a machining area main body (1), and is characterized in that a conveying assembly (45) is arranged at one end of the machining area main body (1), and a clamping processing assembly (46) is arranged on the conveying assembly (45) close to the top of the machining area main body (1);

the conveying assembly (45) comprises a fixed box (47), a conveying placing box (48) and a conveying belt (49), wherein one end of the processing area main body (1) is fixedly connected with the fixed box (47), the fixed box (47) is far away from one end of the processing area main body (1) and is fixedly connected with the conveying placing box (48), the top of the conveying placing box (48) is arranged in a concave mode, the conveying placing box (48) is far away from one end of the fixed box (47) and is fixedly connected with the conveying belt (49), and the conveying belt (49) is close to the end portion of the conveying placing box (48) and corresponds to the groove position at the top of the conveying placing box (48).

2. The device for the numerical control machining center according to claim 1, wherein the conveying assembly (45) further comprises a rotating plate (50) and a first single-head motor (51), a first reserved groove is formed in the inner side of the middle of the conveying placement box (48), sliding grooves are formed in the inner sides of the two sides of the conveying placement box (48) and are communicated with the first reserved groove, the rotating plate (50) is arranged in the inner side of the first reserved groove, the first single-head motor (51) is installed at the bottom of the conveying placement box (48), and the output end of the first single-head motor (51) penetrates through the bottom of the conveying placement box (48) and extends to the inner side of the first reserved groove and is fixedly connected with the rotating plate (50).

3. The device for the numerical control machining center according to claim 2, wherein the conveying assembly (45) further comprises a transmission plate (52), a sliding box (53), pushing displacement blocks (54) and springs (55), the two inner sides of the sliding grooves are all connected with the transmission plate (52) in a sliding mode, the two transmission plates (52) are arranged in an L-shaped mode, the bottoms of the two transmission plates (52) are all extended to the inner sides of the first reserved groove and are in rotary connection fit with the two sides of the rotating plate (50), the tops of the two transmission plates (52) are all fixedly connected with the sliding boxes (53), the two sliding boxes (53) are in sliding connection fit with the conveying placing box (48) and are extended to the inner sides of the grooves of the conveying placing box (48), the pushing displacement blocks (54) are all in sliding connection with the inner sides of the sliding boxes (53), the positions of the two pushing displacement blocks (54) are symmetrically arranged, the inner sides of the two sliding boxes (53) are all provided with the springs (55), and the two pushing displacement blocks (54) are connected with the two sliding boxes (55).

4. The device for the numerical control machining center according to claim 3, wherein the conveying assembly (45) further comprises a double-headed motor (56), a driving rod (57), a first rotating rod (58), a second rotating rod (59) and a rotating concave plate (60), a second reserved groove is formed in the inner side of the conveying placing box (48), the second reserved groove is formed in the top of the first reserved groove, the double-headed motor (56) is mounted in the inner side of the second reserved groove, driving rods (57) are fixedly connected to two ends of the double-headed motor (56), two supporting grooves are formed in the groove in the top of the conveying placing box (48), first rotating rods (58) are connected to the inner sides of the two supporting grooves in a rotating mode, the other ends of the two first rotating rods (58) are connected to the second rotating rods (59) in a rotating mode, one ends of the driving rods (57) away from the double-headed motor (56) are connected to the two first rotating rods (58) and the two second rotating rods (59) in a rotating mode, and the two rotating concave plates (60) are connected to the two rotating concave plates) are arranged at the two ends of the two rotating plates.

5. The device for the numerical control machining center according to claim 1, wherein the clamping processing assembly (46) comprises a six-axis mechanical arm (61), a fixed cylindrical arm (62), first connecting strips (63) and a fixed disc (64), the six-axis mechanical arm (61) is installed on one side of the top of the fixed box (47), the six-axis mechanical arm (61) is far away from the fixed cylindrical arm (62) which is fixedly connected with the end of the fixed box (47), four first connecting strips (63) are fixedly connected with the bottom of the fixed cylindrical arm (62), the four first connecting strips (63) are arranged in a circumferential array, and the four first connecting strips (63) are far away from the fixed cylindrical arm (62) which is fixedly connected with the fixed disc (64).

6. The device for a numerical control machining center according to claim 5, wherein the clamping processing assembly (46) further comprises a first telescopic rod (65), a displacement disc (66), a grabbing clamp (67) and a connecting rotating rod (68), the first telescopic rod (65) is fixedly connected to the bottom of the fixed cylindrical arm (62), the first telescopic rod (65) penetrates through the inner side of the fixed disc (64) and extends to the bottom of the fixed disc (64), the end portion of the first telescopic rod (65) is fixedly connected with the displacement disc (66), a plurality of grabbing clamps (67) are rotatably connected to the bottom of the fixed disc (64), a plurality of grabbing clamps (67) are arranged in a circumferential array, a plurality of connecting rotating rods (68) are rotatably connected to the outer side of the displacement disc (66), and one end, far away from the displacement disc (66), of each connecting rotating rod (68) is in rotary connection with each grabbing clamp (67).

7. The device for the numerical control machining center according to claim 6, wherein the clamping processing assembly (46) further comprises a rotating ring arm (69), a second connecting bar (70), buckling plates (71) and a second single-head motor (72), the rotating ring arm (69) is rotatably matched with the outer side of the fixed cylindrical arm (62), the end portion, away from the fixed box (47), of the six-axis mechanical arm (61) is provided with a motor, the motor is located on the inner side of the fixed cylindrical arm (62) and drives the rotating ring arm (69) to rotate, the second connecting bars (70) are fixedly connected to two sides of the rotating ring arm (69), buckling plates (71) are rotatably connected to the bottoms of the two second connecting bars (70), the second single-head motors (72) are arranged at the connecting positions of the two buckling plates (71) and the two second connecting bars (70), and the two second single-head motors (72) drive the two buckling plates (71) to rotate.

8. The device for the numerical control machining center according to claim 7, wherein the clamping processing assembly (46) further comprises a liquid outlet pipe (73), polishing columns (74) and liquid pumping drives (75), a plurality of liquid outlet pipes (73) are arranged on adjacent sides of the two buckling plates (71), a plurality of liquid outlet holes are formed in inner sides of the liquid outlet pipes (73), a plurality of polishing columns (74) are fixedly connected to outer sides of the liquid outlet pipes (73), liquid pumping drives (75) are fixedly connected to the sides, away from each other, of the two buckling plates (71), and the two liquid pumping drives (75) are communicated with the liquid outlet pipes (73) through a plurality of liquid conveying pipes.

9. The device for a numerical control machining center according to claim 8, wherein the clamping processing assembly (46) further comprises a first fixed ring disc (76), a second fixed ring disc (77), a rotating disc (78), a connecting rotating column (79) and a third single-head motor (80), the first fixed ring disc (76) and the second fixed ring disc (77) are fixedly connected to one side, close to the liquid suction driving (75), of the two buckling plates (71), the two first fixed ring discs (76) are located at the bottoms of the two liquid suction driving (75), the two second fixed ring discs (77) are located at the bottoms of the two first fixed ring discs (76), the inner sides of the two first fixed ring discs (76) and the two second fixed ring discs (77) are rotatably connected with the rotating disc (78), a plurality of circular grooves are formed in the inner sides of each rotating disc (78), the connecting rotating motor (79) is arranged between the two rotating discs (78), the two rotating column (78) is rotatably connected with the two fixed ring discs (78), the two rotating column (78) are rotatably connected with the two fixed ring discs (80), and the output ends of the two third single-head motors (80) penetrate through the two second fixed ring plates (77) and are fixedly connected with the connecting rotating column (79).

10. The device for the numerical control machining center according to claim 9, wherein the clamping processing assembly (46) further comprises a sliding placement seat (81), a second telescopic rod (82) and a lifting plate (83), the inner sides of round grooves formed by the two bottom rotating plates (78) are all connected with a plurality of sliding placement seats (81) in a sliding mode, lifting grooves are formed in the outer sides of the sliding placement seats (81), driving grooves are formed in the outer sides of the two buckling plates (71), the driving grooves are located between the two first fixed annular plates (76) and the two second fixed annular plates (77), the inner sides of the driving grooves are fixedly connected with the second telescopic rods (82), the bottoms of the two second telescopic rods (82) are fixedly connected with the lifting plates (83), and the lifting plates (83) are in clearance fit with the lifting grooves of the sliding placement seats (81).