CN220008049U - Numerical control slotting and punching integrated machine - Google Patents

Abstract

The utility model belongs to the technical field of plate processing equipment, and discloses a numerical control slotting and punching integrated machine which comprises a frame, wherein a double-walking gantry device is movably arranged on the frame, the double-walking gantry device moves along the length direction of the frame, a plate positioning device for positioning a plate to be processed is arranged on the frame, a longitudinal slotting device for forming a longitudinal slot, a transverse slotting device for forming a transverse slot and a drilling device for drilling an opening are arranged on the double-walking gantry device.

Description

Numerical control slotting and punching integrated machine

Technical Field

The utility model belongs to the technical field of plate processing equipment, and particularly relates to a numerical control slotting and punching integrated machine.

Background

Existing boards are various, such as wood boards, PVC boards, PET boards, foam boards and the like, and in the prior art, the boards need to be processed to obtain products.

When the plate is processed, slotting or drilling is required to be carried out on the surface of the plate, as shown in fig. 1-2, longitudinal grooves 1 and transverse grooves 11 are formed in the surface of the plate, the longitudinal grooves 1 and the transverse grooves 11 are distributed in a staggered mode, and openings 12 are formed in staggered points of the longitudinal grooves 1 and the transverse grooves 11.

When producing above-mentioned type panel, in prior art, need the workman to accomplish by hand, workman intensity of labour is big, and complex operation and production precision are poor, and production efficiency is low to need to drill each hole one by one when drilling, reduce result of use, production operation wastes time and energy, and working strength is big, and work efficiency is low.

Disclosure of Invention

The numerical control slotting and perforating integrated machine has the advantages that the integral structure is simple, the plates can be precisely positioned, the longitudinal and transverse slotting operation and the drilling operation of the plates can be automatically completed after one-time positioning, the use is convenient, the production efficiency can be improved, the manufacturing and production costs are reduced, and the use effect is improved.

In order to solve the technical problems, the utility model provides the following technical scheme:

the utility model provides a numerical control slotting and punching all-in-one, includes the frame, and movable mounting has two walking planer-type devices in the frame, and two walking planer-type devices remove along the length direction of frame, are provided with the panel positioner who is used for treating the panel of processing in the frame, install on the two walking planer-type devices and be used for seting up the vertical fluting device in vertical groove, be used for seting up the horizontal fluting device in horizontal groove and be used for boring the drilling equipment who establishes the trompil.

The following is a further optimization of the above technical solution according to the present utility model:

the plate positioning device comprises a vacuum adsorption seat fixedly installed on the frame, a placement position is arranged on the vacuum adsorption seat, and a plurality of positioning plates are respectively arranged around the vacuum adsorption seat.

Further optimizing: the double-travelling gantry device comprises a first gantry and a second gantry which are slidably mounted on a frame, wherein the first and second gantry are arranged in parallel, connecting beams are fixedly connected between two sides of the first and second gantry respectively, and a gantry driving assembly for driving the first and second gantry to integrally move is mounted on the first gantry.

Further optimizing: the longitudinal slotting device comprises a first movable beam arranged at the position of a second portal frame, a longitudinal saw is rotatably arranged below the first movable beam, and a first direction driving mechanism for driving the first movable beam to lift and longitudinally move is arranged on the second portal frame.

Further optimizing: the first azimuth driving mechanism comprises a longitudinal moving block, the longitudinal moving block is slidably mounted on the second portal frame, and a longitudinal driving assembly for driving the longitudinal moving block to reciprocate along the width direction of the frame is mounted on the longitudinal moving block.

Further optimizing: the vertical movable block is provided with a first lifting seat in a sliding manner, the lower end of the first lifting seat is fixedly connected with a first movable beam, and the vertical movable block is provided with a first lifting driving assembly for driving the first lifting seat to lift.

Further optimizing: the transverse slotting device comprises a second movable beam, the second movable beam is arranged below one side of the first portal frame, a transverse saw is rotatably arranged below the second movable beam, and a second azimuth driving mechanism for driving the second movable beam to horizontally and vertically move is arranged on the first portal frame.

Further optimizing: the second azimuth driving mechanism comprises a second lifting seat, the second lifting seat is slidably mounted on the first portal frame, a second lifting moving assembly for driving the second lifting seat to lift is mounted on the first portal frame, and the lower end of the second lifting seat is slidably connected with the second moving beam; and a horizontal moving assembly for driving the second moving beam to horizontally move is arranged on the second lifting seat.

Further optimizing: the drilling device comprises a movable seat, the movable seat is slidably mounted on the first portal frame and is far away from one side of the transverse slotting device, a third lifting seat is slidably mounted on the movable seat, and a plurality of groups of drilling bags are fixedly mounted below the third lifting seat.

Further optimizing: the first portal frame is provided with a moving driving assembly for driving the moving seat to horizontally move; and a third lifting driving assembly for driving the third lifting seat to lift is arranged on the movable seat.

By adopting the technical scheme, the utility model has ingenious conception and reasonable structure, can position and place the plate to be processed, can move the plate to be processed, can open the longitudinal groove and the transverse groove on the plate to be processed, and can drill the plate to be processed, thereby being convenient to operate, reducing the labor intensity of workers, improving the use effect, improving the production rate, reducing the labor cost and reducing the production cost during use.

And overall structure is simple, and convenient preparation and production can reduce manufacturing cost, and degree of automation is high, can accomplish fluting and drilling operation to panel in the one-time positioning process is automatic, improves production precision, improves result of use.

The utility model will be further described with reference to the drawings and examples.

Drawings

FIG. 1 is a sheet material finished product produced in the background art;

fig. 2 is a partial enlarged view at a in fig. 1.

FIG. 3 is a schematic diagram of the overall structure of an embodiment of the present utility model;

FIG. 4 is a front view of the overall structure of an embodiment of the present utility model;

FIG. 5 is a partial enlarged view at B in FIG. 3;

FIG. 6 is a schematic view of a double-travelling gantry apparatus according to an embodiment of the present utility model;

FIG. 7 is a schematic view of a longitudinal slotting device according to an embodiment of the present utility model;

FIG. 8 is a schematic view of a longitudinal slotting device according to another embodiment of the present utility model;

FIG. 9 is a schematic structural view of a transverse slotting device according to an embodiment of the present utility model;

FIG. 10 is an enlarged view of a portion of FIG. 9 at C;

FIG. 11 is a schematic structural view of a drilling device according to an embodiment of the present utility model;

fig. 12 is a schematic structural diagram of a drill package according to an embodiment of the present utility model.

1-longitudinal grooves in the figure; 11-a transverse slot; 12-perforating; 2-a frame; 21-a base slide rail; 22-a base rack; 3-a plate positioning device; 31-a vacuum adsorption seat; 32-positioning plates; 4-double-travelling gantry means; 41-a first portal frame; 42-a second portal frame; 43-connecting beams; 44-a walking motor; 45-a walking gear; 46-a base slide; 5-a longitudinal slotting device; 501-a first moving beam; 502-longitudinal saw; 5021-a first central axis; 5022-a first slotted saw blade; 503-a first lifting seat; 504-a longitudinal movement block; 505-longitudinal saw drive motor; 506-a first dust hood; 507-a first slide rail; 508-a first slider; 509-a longitudinal drive motor; 510-a longitudinal drive gear; 511-longitudinal rack; 512-second slide rail; 513-a second slider; 514-a first drive motor; 515-a first balancing cylinder; 6-a transverse slotting device; 601-a second moving beam; 602-a transverse saw; 6021-second central axis; 6022-a second slotted saw blade; 603-a second lifting seat; 604-a second drive motor; 605-a transverse saw drive motor; 606-a second dust hood; 607-a third slide rail; 609-a moving cylinder; 610-fourth slide rail; 611-fourth slider; 7-a drilling device; 701-a mobile seat; 702-a third lifting seat; 703-drilling a package; 7031-a gear box; 7032-drill bit; 7033-a drill package motor; 704-a fifth slide rail; 705-fifth slider; 706-a mobile motor; 707—a third lead screw; 708-sixth slide rail; 709-sixth slider; 710—a third drive motor; 711-a third balancing cylinder; 712-top plate; 713-mounting plate; 714-top connection cylinder; 715-guide posts; 716-a buffer spring.

Detailed Description

As shown in fig. 1-12, a numerical control slotting and punching integrated machine comprises a frame 2, wherein a double-walking gantry device 4 is movably installed on the frame 2, the double-walking gantry device 4 moves along the length direction of the frame 2, a plate positioning device 3 for positioning a plate to be processed is arranged on the frame 2, and a longitudinal slotting device 5 for forming a longitudinal slot 1, a transverse slotting device 6 for forming a transverse slot 11 and a drilling device 7 for drilling an opening 12 are installed on the double-walking gantry device 4.

The plate positioning device 3 comprises a vacuum adsorption seat 31 fixedly installed on the frame 2, and a placement position is arranged on the vacuum adsorption seat 31, and a plate to be processed can be placed on the placement position.

A plurality of positioning plates 32 are respectively arranged around the vacuum adsorption seat 31, and the upper ends of the positioning plates 32 extend to the upper side of the vacuum adsorption seat 31.

A plurality of slots are formed above the positioning plate 32, and the slots can facilitate the saw blades on the longitudinal slotting device 5 and the transverse slotting device 6 to pass through, so that the use is convenient.

A cavity (not shown) is formed in the vacuum adsorption seat 31, and the cavity is communicated with an external vacuum pump through a communicating pipe.

The upper end surface of the vacuum adsorption seat 31 is provided with a plurality of suction holes (not shown in the figure), and a plurality of suction holes are arranged at intervals along the longitudinal direction and the transverse direction of the vacuum adsorption seat 31.

By such design, the external vacuum pump works to vacuumize the cavity in the vacuum adsorption seat 31, and at this time, negative pressure suction can be generated at the suction hole on the vacuum adsorption seat 31.

When the plate to be processed is placed on the placement position above the vacuum adsorption seat 31, the plate to be processed can be sucked by the negative pressure suction generated at the suction hole on the vacuum adsorption seat 31, so that the use is convenient.

The base sliding rail 21 and the base rack 22 are respectively and fixedly arranged at positions, close to two sides of the frame 2, the base sliding rail 21 and the base rack 22 are arranged in parallel, and the base sliding rail 21 and the base rack 22 are arranged along the length direction of the frame 2.

The double-travelling gantry device 4 comprises a first gantry 41 and a second gantry 42 which are slidably mounted on the frame 2, wherein the first gantry 41 and the second gantry 42 are arranged in parallel.

The lower ends of the first portal frame 41 and the second portal frame 42 are respectively and fixedly connected with a plurality of base sliding blocks 46, and the base sliding blocks 46 are in sliding connection with the corresponding base sliding rails 21.

The first portal frame 41 and the second portal frame 42 are slidably connected to the base slide rail 21 through the base slide block 46, and are slidably mounted on the frame 2.

A connecting beam 43 is respectively arranged between two sides of the first portal frame 41 and the second portal frame 42, and two ends of the connecting beam 43 are respectively fixedly connected with the corresponding first portal frame 41 and second portal frame 42.

By means of the design, the first portal frame 41 and the second portal frame 42 can be fixedly connected into a whole through the connecting beam 43, and then the first portal frame 41 and the second portal frame 42 can synchronously move, so that the use is convenient.

The overall structural strength of the first and second portal frames 41 and 42 can be improved through the connecting beam 43, the supporting force of the first and second portal frames 41 and 42 can be improved, and the use effect can be improved.

The first portal frame 41 is provided with a portal frame driving assembly for driving the first portal frame 41 and the second portal frame 42 to integrally move.

The gantry driving assembly comprises a traveling motor 44 arranged inside the first gantry 41 and close to the two base racks 22, and the two traveling motors 44 are respectively and fixedly arranged in the first gantry 41.

The power output end of the traveling motor 44 penetrates through the lower end face of the first portal frame 41 and is fixedly connected with a traveling gear 45, and the traveling gear 45 is in meshed connection with the base rack 22.

By means of the design, the walking motor 44 outputs power to drive the walking gear 45 to rotate positively and negatively, the walking gear 45 is meshed with the base rack 22, and then the first portal frame 41 can be driven to move along the base slide rail 21, and the use is convenient.

The first portal frame 41 can move through the connecting beam 43 to drive the second portal frame 42 to move, so that the use is convenient.

The longitudinal slotting device 5 comprises a first movable beam 501 arranged at the position of a second portal frame 42, a longitudinal saw 502 is rotatably arranged below the first movable beam 501, and a first direction driving mechanism for driving the first movable beam 501 to lift and longitudinally move is arranged on the second portal frame 42.

The longitudinal saw 502 includes a first central shaft 5021, a plurality of first slotted saw blades 5022 are installed on the first central shaft 5021 at intervals, the first central shaft 5021 is disposed below the first movable beam 501, and two ends of the first central shaft 5021 are respectively connected with the first movable beam 501 in a rotating manner.

The first central shafts 5021 are arranged in parallel with the length direction of the frame 2, and the distance between two adjacent first slotting saw blades 5022 is matched with the distance between two adjacent longitudinal slots 1 to be machined.

The first moving beam 501 is fixedly provided with a longitudinal saw driving motor 505 near two ends thereof, and the power output end of the longitudinal saw driving motor 505 is in transmission connection with the end part of the corresponding first central shaft 5021.

The longitudinal saw driving motor 505 outputs power to drive the first central shaft 5021 to rotate, and the first central shaft 5021 rotates to drive the first slotting saw blade 5022 to rotate.

When the vertical saw is used, the first direction driving mechanism drives the first moving beam 501 to lift and longitudinally move so as to drive the vertical saw 502 to lift and longitudinally move, at this time, the vertical saw driving motor 505 drives the vertical saw 502 to work, and the vertical saw 502 can work to form a vertical groove 1 on a plate to be processed through the first slotting saw blade 5022, so that the vertical saw is convenient to use.

A first dust hood 506 is arranged on one side of the first movable beam 501, which is positioned on the longitudinal saw 502, and the first dust hood 506 is communicated with peripheral dust collection equipment through a dust collection pipeline.

When the longitudinal saw 502 is provided with the longitudinal groove 1 on a plate to be processed, the peripheral dust collection equipment and the first dust collection cover 506 are matched to suck away dust generated during the working of the longitudinal saw 502, so that the use is convenient.

The first azimuth driving mechanism comprises a longitudinal moving block 504, the longitudinal moving block 504 is slidably mounted on the second portal frame 42, and a longitudinal driving assembly for driving the longitudinal moving block 504 to reciprocate along the width direction of the frame 2 is mounted on the longitudinal moving block 504.

The longitudinal moving block 504 is slidably provided with a first lifting seat 503, the lower end of the first lifting seat 503 is fixedly connected with the first moving beam 501, and the longitudinal moving block 504 is provided with a first lifting driving assembly for driving the first lifting seat 503 to lift.

In this embodiment, the longitudinal moving block 504 is slidably connected to the second portal frame 42 through the first sliding rail 507 and the first sliding block 508.

The number of the first sliding rails 507 is two, the two first sliding rails 507 are fixedly mounted on the second portal frame 42, and the first sliding rails 507 are distributed along the width direction of the frame 2.

The number of the first sliding blocks 508 is plural, and the plurality of first sliding blocks 508 are respectively and fixedly installed on the longitudinal moving block 504, and the first sliding blocks 508 are slidably connected with the corresponding first sliding rails 507.

The longitudinal driving assembly comprises a longitudinal driving motor 509 fixedly mounted on the longitudinal moving block 504, and a longitudinal driving gear 510 is fixedly mounted on the power output end of the longitudinal driving motor 509.

The second portal frame 42 is provided with a longitudinal rack 511, the longitudinal rack 511 and the first sliding rail 507 are arranged in parallel, and the longitudinal driving gear 510 is in meshed connection with the longitudinal rack 511.

In this way, the longitudinal driving motor 509 is configured to drive the longitudinal driving gear 510 to rotate, and the longitudinal driving gear 510 is in meshed connection with the longitudinal rack 511, so that the longitudinal moving block 504 can be driven to move along the first sliding rail 507, which is convenient for use.

The longitudinal moving block 504 moves through the first lifting seat 503 to drive the first moving beam 501 to move, and the first lifting driving assembly is used for driving the first lifting seat 503 to lift, and at this time, the first lifting seat 503 can drive the first moving beam 501 to lift.

The longitudinal moving block 504 is slidably connected with the first lifting seat 503 through the cooperation of the second sliding rail 512 and the second sliding block 513.

The number of the second sliding rails 512 is two, and the two second sliding rails 512 are fixedly mounted on the longitudinal moving block 504, and the second sliding rails 512 are vertically arranged.

The number of the second sliding blocks 513 is plural, and the plurality of second sliding blocks 513 are respectively and fixedly installed on the first lifting seat 503, and the second sliding blocks 513 are slidably connected with the corresponding second sliding rails 512.

By means of the design, the first lifting seat 503 can be slidably mounted on the longitudinal moving block 504 through the cooperation of the second sliding rail 512 and the second sliding block 513, and assembly and installation are convenient.

The first lifting driving assembly includes a first driving motor 514 fixedly installed on the longitudinal moving block 504, and a first lead screw (not shown in the figure) is fixedly connected to a power output end of the first driving motor 514, and the first lead screw and the second sliding rail 512 are arranged in parallel.

A first moving block (not shown in the figure) is connected to the first screw through a screw thread, and the first moving block is fixedly connected to the first lifting seat 503.

In this design, the first driving motor 514 is used to drive the first screw to rotate, the first screw rotates and drives the first moving block to move, and the first moving block can drive the first lifting seat 503 to move, so that the use is convenient.

A plurality of first balancing cylinders 515 are disposed above the first lifting seat 503, and the first balancing cylinders 515 are disposed along the moving direction of the first lifting seat 503.

The telescopic end of the first balancing cylinder 515 is fixedly connected with the first lifting seat 503, and the fixed end of the first balancing cylinder 515 is fixedly mounted on the longitudinal moving block 504 through a fixed connection seat (not shown in the figure), so that the assembly and the installation are convenient.

By means of the design, the first driving motor 514, the first lead screw and the first moving block can be assisted to synchronously drive the first lifting seat 503 to lift through the first balance air cylinder 515, so that the use effect is improved, and the use is convenient.

Therefore, the longitudinal driving motor 509 can be used for driving the longitudinal driving gear 510 to rotate, and the longitudinal driving gear 510 is in meshed connection with the longitudinal rack 511, so that the longitudinal moving block 504 can be driven to move along the first sliding rail 507, and the use is convenient.

The longitudinal moving block 504 moves through the first lifting seat 503, so that the first moving beam 501 and the longitudinal saw 502 can be driven to move.

The first balancing cylinder 515 and the first driving motor 514 work synchronously, the first driving motor 514 is used for driving the first screw rod to rotate, the first screw rod rotates to drive the first moving block to move, and the first moving block can drive the first lifting seat 503 to lift and move, so that the use is convenient.

The first lifting seat 503 can drive the first moving beam 501 and the longitudinal saw 502 to lift.

The transverse slotting device 6 comprises a second movable beam 601, the second movable beam 601 is arranged below one side of the first portal frame 41, a transverse saw 602 is rotatably arranged below the second movable beam 601, and a second azimuth driving mechanism for driving the second movable beam 601 to horizontally and vertically move is arranged on the first portal frame 41.

The cross saw 602 includes a second central shaft 6021, a plurality of second slotted saw blades 6022 are installed on the second central shaft 6021 at intervals, the second central shaft 6021 is disposed below the second movable beam 601, and two ends of the second central shaft 6021 are respectively connected with the second movable beam 601 in a rotating manner.

The second central shaft 6021 is arranged in parallel with the width direction of the frame 2, and the interval between two adjacent second slotting saw blades 6022 is matched with the interval between two adjacent transverse slots 11 to be processed.

The second movable beam 601 is fixedly provided with a transverse saw driving motor 605 near the two ends thereof, and the power output end of the transverse saw driving motor 605 is in transmission connection with the end part of the corresponding second central shaft 6021.

The power output by the transverse saw driving motor 605 can drive the second central shaft 6021 to rotate, and the second central shaft 6021 rotates to drive the second slotting saw blade 6022 to rotate.

When the horizontal saw is used, the second azimuth driving mechanism drives the second moving beam 601 to lift and horizontally move, so that the horizontal saw 602 can be driven to lift and horizontally move, at the moment, the horizontal saw driving motor 605 drives the horizontal saw 602 to work, and the horizontal saw 602 can work to form a horizontal groove 11 on a plate to be processed through the second slotting saw blade 6022, so that the horizontal saw is convenient to use.

A second dust hood 606 is arranged on one side of the second movable beam 601, which is positioned on the transverse saw 602, and the second dust hood 606 is communicated with peripheral dust collection equipment through a dust collection pipeline.

When the transverse saw 602 is provided with the transverse groove 11 on the plate to be processed, the peripheral dust collection equipment and the second dust hood 606 are matched to suck away dust generated during the working of the transverse saw 602, so that the use is convenient.

The second azimuth driving mechanism comprises a second lifting seat 603, the second lifting seat 603 is slidably mounted on the first portal frame 41, and a second lifting moving component for driving the second lifting seat 603 to lift is mounted on the first portal frame 41.

The lower end of the second lifting seat 603 is slidably connected with the second movable beam 601; the second elevating seat 603 is provided with a horizontal movement assembly for driving the second movement beam 601 to horizontally move.

The first gantry 41 is provided with a second lifting and moving assembly for driving the second lifting and moving seat 603 to lift and move.

The second lifting seat 603 is slidably connected with the first portal frame 41 through a third sliding rail 607 and a third sliding block (not shown in the figure).

The number of the third sliding rails 607 is two, and the two third sliding rails 607 are fixedly installed on the first portal frame 41, and the third sliding rails 607 are vertically arranged.

The number of the third sliding blocks is multiple, the plurality of the third sliding blocks are respectively and fixedly installed on the second lifting seat 603, and the third sliding blocks are in sliding connection with the corresponding third sliding rails 607.

By means of the design, the second lifting seat 603 can be slidably mounted on the first portal frame 41 through the cooperation of the third sliding rail 607 and the third sliding block, and assembly and installation are convenient.

The second lifting moving assembly comprises a second driving motor 604 fixedly installed on the first portal frame 41, a second lead screw (not shown in the figure) is connected to the power output end of the second driving motor 604 in a transmission manner, and the second lead screw and the third sliding rail 607 are arranged in parallel.

The second screw is rotatably mounted on the first portal frame 41, and is in threaded connection with a second moving block (not shown in the figure), and the second moving block is fixedly connected with the second lifting seat 603.

In this way, the second driving motor 604 is used to drive the second screw to rotate, the second screw rotates to drive the second moving block to move, and the second moving block can drive the second lifting seat 603 to move, so that the use is convenient.

In this embodiment, a plurality of second balancing cylinders may be further disposed above the second lifting seat 603, the second balancing cylinders are disposed along the moving direction of the second lifting seat 603, the telescopic ends of the second balancing cylinders are fixedly connected with the second lifting seat 603, and the fixed ends of the second balancing cylinders are fixedly mounted on the first portal frame 41.

By means of the design, the second driving motor 604, the second lead screw and the second moving block can be assisted to synchronously drive the second lifting seat 603 to lift and move through the second balancing cylinder, so that the using effect is improved, and the use is convenient.

The second lifting seat 603 and the second moving beam 601 are slidably connected by matching the fourth sliding rail 610 and the fourth sliding block 611.

The fourth sliding rails 610 are multiple channels, the multiple channels of the fourth sliding rails 610 are arranged in parallel and at intervals, the fourth sliding rails 610 are fixedly mounted on the second moving beam 601, and the fourth sliding rails 610 are arranged along the length direction of the second moving beam 601.

The number of the fourth sliding blocks 611 is plural, and the plurality of fourth sliding blocks 611 are respectively and fixedly mounted on the second lifting seat 603, and the fourth sliding blocks 611 are respectively and slidably connected with the corresponding fourth sliding rails 610.

By means of the design, the second moving beam 601 can be slidably mounted on the second lifting seat 603 through the cooperation of the fourth sliding rail 610 and the fourth sliding block 611, and the second lifting seat is convenient to assemble and install and convenient to use.

The horizontal moving assembly comprises a moving air cylinder 609 fixedly installed on the second lifting seat 603, the moving air cylinder 609 and the fourth sliding rail 610 are arranged in parallel, and the telescopic end of the moving air cylinder 609 is fixedly connected with the second moving beam 601 through a connecting plate.

By means of the design, the movable air cylinder 609 outputs power to enable the telescopic end of the movable air cylinder 609 to extend or retract, and at the moment, the movable air cylinder 609 can drive the second movable beam 601 to horizontally move through the connecting plate, so that the movable air cylinder is convenient to use.

In this way, when in use, the second driving motor 604 is used to drive the second screw to rotate, the second screw rotates and can drive the second moving block to move, and the second moving block can move to drive the second lifting seat 603 to lift.

The second lifting seat 603 can drive the transverse saw 602 to lift and move through the second moving beam 601, and the use is convenient.

The moving cylinder 609 outputs power to enable the telescopic end of the moving cylinder 609 to extend or retract, and at the moment, the moving cylinder 609 can drive the second moving beam 601 to horizontally move through the connecting plate.

The second moving beam 601 moves horizontally to drive the transverse saw 602 to move horizontally, so as to adjust the position of the transverse saw 602, and the use is convenient.

The drilling device 7 comprises a moving seat 701, the moving seat 701 is slidably mounted on the first portal frame 41 and is far away from one side of the transverse slotting device 6, a third lifting seat 702 is slidably mounted on the moving seat 701, and a plurality of groups of drilling bags 703 are fixedly mounted below the third lifting seat 702.

The drill bag 703 comprises a transmission case 7031, a plurality of drill bits 7032 are rotatably mounted on the transmission case 7031 near the lower position of the transmission case 7031, and the drill bits 7032 are distributed at intervals along the length direction of the transmission case 7031.

The drilling and packing motors 7033 are fixedly arranged at positions, close to two ends, of the transmission case 7031, transmission assemblies for driving the drill bits 7032 to synchronously rotate are arranged in the transmission case 7031, and the drilling and packing motors 7033 are respectively in transmission connection with power input ends of the transmission assemblies.

So designed, the power output by the drill package motor 7033 drives each drill 7032 to synchronously rotate through a transmission assembly, and each drill 7032 rotates to drill a plate.

In this embodiment, the transmission assembly is in the prior art, and a gear set may be used for transmission.

In this embodiment, the drill packages 703 are multiple groups, and the multiple groups of drill packages 703 are distributed at equal intervals, and the gear boxes 7031 of the multiple groups of drill packages 703 are respectively and fixedly installed at the lower position of the third lifting seat 702, so that the assembly and the installation are convenient.

The movable seat 701 is slidably connected with the first portal frame 41 through the cooperation of the fifth sliding rail 704 and the fifth sliding block 705.

The number of the fifth sliding rails 704 is two, the two fifth sliding rails 704 are arranged in parallel, the fifth sliding rails 704 are fixedly mounted on the first portal frame 41, and the fifth sliding rails 704 are arranged along the width direction of the frame 2.

The number of the fifth sliding blocks 705 is plural, the plurality of fifth sliding blocks 705 are respectively and fixedly installed on the movable seat 701, and the fifth sliding blocks 705 are respectively and slidably connected with the corresponding fifth sliding rails 704.

By means of the design, the movable seat 701 can be slidably mounted on the first portal frame 41 through the cooperation of the fifth sliding rail 704 and the fifth sliding block 705, assembly and installation are convenient, and the movable seat 701 can move along the fifth sliding rail 704, so that use is convenient.

The first gantry 41 is provided with a movement driving assembly for driving the movement base 701 to horizontally move.

The moving driving assembly comprises a moving motor 706 fixedly arranged on the first portal frame 41, and a third lead screw 707 is connected to the power output end of the moving motor 706 in a transmission manner.

The other end of the third screw rod 707 is connected to a bearing block, and the bearing block is fixedly mounted on the first gantry 41.

The third screw rod 707 and the fifth sliding rail 704 are arranged in parallel, and a third moving block (not shown in the figure) is screwed on the third screw rod 707 and is fixedly connected with the moving seat 701.

In this way, the moving motor 706 is used to drive the third screw rod 707 to rotate, the third screw rod 707 rotates to drive the third moving block to move, and the third moving block can drive the moving seat 701 to move, so that the use is convenient.

The third lifting seat 702 is slidably connected with the moving seat 701 through the cooperation of a sixth sliding rail 708 and a sixth sliding block 709.

The number of the sixth sliding rails 708 is multiple, and the multiple sixth sliding rails 708 are respectively and fixedly mounted on the movable seat 701, and the sixth sliding rails 708 are vertically arranged.

The number of the sixth sliding blocks 709 is plural, and the plurality of sixth sliding blocks 709 are respectively and fixedly installed on the third lifting seat 702, and the sixth sliding blocks 709 are slidably connected with the corresponding sixth sliding rails 708.

By means of the design, the third lifting seat 702 can be slidably mounted on the movable seat 701 through the cooperation of the sixth sliding rail 708 and the sixth sliding block 709, and assembly and installation are convenient.

And the third lifting seat 702 can be supported to lift through the cooperation of the sixth sliding rail 708 and the sixth sliding block 709, so that the height position of the drill bag 703 can be adjusted, and the use is convenient.

The movable seat 701 is provided with a third lifting driving assembly for driving the third lifting seat 702 to lift.

The third lifting driving assembly comprises a third driving motor 710 fixedly installed on the moving seat 701, and a fourth screw (not shown in the figure) is connected to the power output end of the third driving motor 710 in a transmission manner, and the fourth screw and the sixth sliding rail 708 are arranged in parallel.

The fourth screw is rotatably mounted on the moving seat 701, and is in threaded connection with a fourth moving block (not shown in the figure), and the fourth moving block is fixedly connected with the third lifting seat 702.

In this way, the third driving motor 710 is used to drive the fourth screw to rotate, the fourth screw rotates to drive the fourth moving block to move, and the fourth moving block can drive the third lifting seat 702 to lift and move, so that the use is convenient.

In addition to this embodiment, a plurality of third balancing cylinders 711 may be disposed above the third lifting seat 702, where the third balancing cylinders 711 are disposed along the moving direction of the third lifting seat 702, the telescopic ends of the third balancing cylinders 711 are fixedly connected to the third lifting seat 702, and the fixed ends of the third balancing cylinders 711 are fixedly mounted on the moving seat 701 through a connecting seat (not shown in the drawing).

By means of the design, the third driving motor 710, the third lead screw 707 and the third moving block can be assisted to synchronously drive the third lifting seat 702 to lift through the third balance air cylinder 711, so that the use effect is improved, and the use is convenient.

In this way, the moving motor 706 is used to drive the third screw rod 707 to rotate, the third screw rod 707 rotates to drive the third moving block to move, and the third moving block can drive the moving seat 701 to move on the fifth sliding rail 704, so that the use is convenient.

The moving seat 701 moves to drive the multiple groups of drilling bags 703 to move through the third lifting seat 702, so as to adjust the positions of the drilling bags 703.

The third driving motor 710 is operative to drive the fourth screw to rotate, the fourth screw rotates and drives the fourth moving block to move, and the fourth moving block can drive the third lifting seat 702 to lift on the sixth sliding rail 708 for convenient use.

The third lifting seat 702 can drive the multiple groups of drilling bags 703 to lift, so that the height position of the drilling bags 703 can be adjusted, and the use is convenient.

Two propping plates 712 are arranged below the drill package 703, the two propping plates 712 are respectively arranged in parallel, and a propping driving assembly for driving the propping plates 712 to move up and down is arranged above the drill package 703.

The jacking driving assembly comprises two mounting plates 713 fixedly mounted on the plurality of drilling bags 703, and the two mounting plates 713 are respectively arranged on the plurality of drilling bags 703 near two ends of the drilling bags 703.

The mounting plate 713 is fixedly provided with a jacking cylinder 714, and the telescopic end of the jacking cylinder 714 penetrates through the mounting plate 713 and is fixedly connected with the jacking plate 712.

The mounting plate 713 is also movably provided with a guide post 715, and the lower end of the guide post 715 penetrates through the mounting plate 713 and is fixedly connected with the top connection plate 712.

The guide post 715 is slidably connected to the mounting plate 713.

In this way, the jacking cylinder 714 outputs power to extend or retract the telescopic end, and the jacking cylinder 714 can drive the jacking plate 712 to move up or down.

The propping plate 712 moves up or down to drive the guide post 715 to move, and at this time, the sliding connection between the guide post 715 and the mounting plate 713 can guide the movement of the propping plate 712, so as to improve the use effect.

Buffer springs 716 are fixedly arranged below the jacking plate 712 and near the two ends of the jacking plate.

In this way, when the drilling of the drill bit 7032 on the drilling bag 703 is completed during use, the third lifting seat 702 is lifted to drive the drill bit 7032 to move upwards, at this time, the jacking cylinder 714 outputs power to enable the telescopic end of the telescopic end to extend, the jacking cylinder 714 can drive the jacking plate 712 to move downwards, and at this time, the jacking plate 712 drives the buffer spring 716 to move downwards to contact with the plate to be processed.

At this time, the drill 7032 can be conveniently pulled out of the hole 12 by the downward movement of the top plate 712 and the upward movement of the third lifting base 702, thereby facilitating the use.

And the buffer spring 716 can buffer the abutting plums of the abutting plate 712, so that the use effect is improved.

When in use, firstly, the plate to be processed is placed on the placement position above the vacuum adsorption seat 31, and the vacuum adsorption seat 31 works to suck the plate to be processed by the negative pressure suction generated by the suction hole, so that the use is convenient.

When the longitudinal groove 1 is required to be formed in the plate to be processed, the traveling motor 44 on the first portal frame 41 outputs power to drive the traveling gear 45 to rotate positively and negatively, the traveling gear 45 is in meshed connection with the base rack 22, and then the first portal frame 41 and the second portal frame 42 can be driven to move along the base slide rail 21, so that the position of the longitudinal saw 502 is adjusted.

After the position adjustment of the longitudinal saw 502 is completed, the first balancing cylinder 515 and the first driving motor 514 work synchronously, the first driving motor 514 is used for driving the first screw rod to rotate, the first screw rod rotates to drive the first moving block to move, the first moving block can drive the first lifting seat 503 to lift and move, further drive the first moving beam 501 and the longitudinal saw 502 to lift and move, and the first slotted saw blade 5022 of the longitudinal saw 502 is in contact with a plate to be processed.

Then, the longitudinal saw driving motor 505 works to drive the longitudinal saw 502 to work, and the longitudinal saw 502 can be used conveniently by forming the longitudinal groove 1 on the plate to be processed through the first grooving saw blade 5022.

And the longitudinal driving motor 509 is used for driving the longitudinal driving gear 510 to rotate, and the longitudinal driving gear 510 is in meshed connection with the longitudinal rack 511, so that the longitudinal moving block 504 can be driven to move along the first sliding rail 507, and the use is convenient.

The longitudinal moving block 504 moves through the first lifting seat 503, so that the first moving beam 501 and the longitudinal saw 502 can be driven to move.

It can be seen that the longitudinal groove 1 can be formed in the plate to be processed through the cooperation of the longitudinal saw 502, the longitudinal saw driving motor 505, the longitudinal driving motor 509, the first driving motor 514 and the first balancing cylinder 515, so that the use is convenient.

When the transverse groove 11 is required to be formed in the plate to be processed, the traveling motor 44 on the first portal frame 41 outputs power to drive the traveling gear 45 to rotate positively and negatively, the traveling gear 45 is meshed with the base rack 22, and then the first portal frame 41 and the second portal frame 42 can be driven to move along the base slide rail 21, so that the position of the transverse saw 602 is adjusted.

After the position of the transverse saw 602 is adjusted, the second driving motor 604 is used for driving the second screw to rotate, the second screw can drive the second moving block to move, and the second moving block can drive the second lifting seat 603 to lift.

The second lifting seat 603 can drive the transverse saw 602 to lift through the second moving beam 601, and the second slotted saw blade 6022 of the transverse saw 602 is contacted with the plate to be processed.

The transverse saw driving motor 605 drives the transverse saw 602 to work, and the transverse saw 602 can be used conveniently by forming the transverse groove 11 on the plate to be processed through the second grooving saw blade 6022.

And the traveling motor 44 on the first portal frame 41 outputs power to drive the traveling gear 45 to rotate positively and negatively, and the traveling gear 45 is meshed with the base rack 22, so that the first portal frame 41 and the second portal frame 42 can be driven to move along the base slide rail 21, and the position of the transverse saw 602 is adjusted.

It can be seen that the transverse grooves 11 can be formed in the plate to be processed through the cooperation of the transverse saw 602, the transverse saw driving motor 605, the traveling motor 44 and the second driving motor 604, and the use is convenient.

And when the transverse groove 11 is formed, the moving cylinder 609 outputs power to enable the telescopic end of the moving cylinder 609 to extend or retract, and at the moment, the moving cylinder 609 can drive the second moving beam 601 to horizontally move through the connecting plate.

The second moving beam 601 moves horizontally to drive the transverse saw 602 to move horizontally, so as to adjust the position of the transverse saw 602, and the use is convenient.

When the hole 12 is required to be drilled in the plate to be processed, the traveling motor 44 on the first portal frame 41 outputs power to drive the traveling gear 45 to rotate positively and negatively, the traveling gear 45 is meshed with the base rack 22, and then the first portal frame 41 and the second portal frame 42 can be driven to move along the base slide rail 21, so that the position of the drilling device 7 is adjusted.

And then the moving motor 706 is used for driving the third lead screw 707 to rotate, the third lead screw 707 rotates to drive the third moving block to move, and the third moving block can drive the moving seat 701 to move, so that the moving seat 701 moves to adjust the position of the drill bag 703.

After the position of the drill bag 703 is adjusted, the third driving motor 710 is used to drive the fourth screw to rotate, the fourth screw rotates to drive the fourth moving block to move, the fourth moving block can drive the third lifting seat 702 to lift, and the third lifting seat 702 can drive the drill bag 703 to move downwards.

At this time, the power output by the drilling pack motor 7033 on the drilling pack 703 drives each drill bit 7032 to synchronously rotate through the transmission assembly, and each drill bit 7032 rotates to drill the plate.

When the drilling of the drill bit 7032 on the drilling bag 703 is completed, the third lifting seat 702 is lifted to drive the drill bit 7032 to move upwards, at this time, the top connection cylinder 714 outputs power to enable the telescopic end of the telescopic end to extend, the top connection cylinder 714 can drive the top connection plate 712 to move downwards, and at this time, the top connection plate 712 drives the buffer spring 716 to move downwards to contact with the plate to be processed.

At this time, the drill 7032 can be conveniently pulled out of the hole 12 by the downward movement of the top plate 712 and the upward movement of the third lifting base 702, thereby facilitating the use.

And the buffer spring 716 can buffer the abutting plums of the abutting plate 712, so that the use effect is improved.

Alterations, modifications, substitutions and variations of the embodiments herein will be apparent to those of ordinary skill in the art in light of the teachings of the present utility model without departing from the spirit and principles of the utility model.

Claims (10)

1. The utility model provides a numerical control slotting and punching all-in-one, includes frame (2), its characterized in that: the double-walking gantry device (4) is movably mounted on the frame (2), the double-walking gantry device (4) moves along the length direction of the frame (2), the frame (2) is provided with a plate positioning device (3) for positioning a plate to be processed, and the double-walking gantry device (4) is provided with a longitudinal slotting device (5) for forming a longitudinal slot (1), a transverse slotting device (6) for forming a transverse slot (11) and a drilling device (7) for drilling a hole (12).

2. The numerical control slotting and perforating integrated machine according to claim 1, wherein: the plate positioning device (3) comprises a vacuum adsorption seat (31) fixedly arranged on the frame (2), a placement position is arranged on the vacuum adsorption seat (31), and a plurality of positioning plates (32) are respectively arranged around the vacuum adsorption seat (31).

3. The numerical control slotting and perforating integrated machine according to claim 2, characterized in that: the double-travelling gantry device (4) comprises a first gantry (41) and a second gantry (42) which are slidably mounted on a frame (2), the first gantry (41) and the second gantry (42) are arranged in parallel, connecting beams (43) are fixedly connected between two sides of the first gantry (41) and two sides of the second gantry (42) respectively, and a gantry driving assembly for driving the first gantry (41) and the second gantry (42) to integrally move is mounted on the first gantry (41).

4. A numerically controlled slotting and perforating integrated machine as in claim 3, wherein: the longitudinal slotting device (5) comprises a first movable beam (501) arranged at the position of a second portal frame (42), a longitudinal saw (502) is rotatably arranged below the first movable beam (501), and a first direction driving mechanism for driving the first movable beam (501) to lift and longitudinally move is arranged on the second portal frame (42).

5. The numerical control slotting and perforating integrated machine according to claim 4, wherein: the first azimuth driving mechanism comprises a longitudinal moving block (504), the longitudinal moving block (504) is slidably mounted on the second portal frame (42), and a longitudinal driving assembly for driving the longitudinal moving block (504) to reciprocate along the width direction of the frame (2) is mounted on the longitudinal moving block (504).

6. The numerical control slotting and perforating integrated machine according to claim 5, wherein: the vertical moving block (504) is provided with a first lifting seat (503) in a sliding manner, the lower end of the first lifting seat (503) is fixedly connected with the first moving beam (501), and the vertical moving block (504) is provided with a first lifting driving assembly for driving the first lifting seat (503) to lift.

7. The numerical control slotting and perforating integrated machine according to claim 6, wherein: the transverse slotting device (6) comprises a second movable beam (601), the second movable beam (601) is arranged below one side of the first portal frame (41), a transverse saw (602) is rotatably arranged below the second movable beam (601), and a second azimuth driving mechanism for driving the second movable beam (601) to horizontally and vertically move is arranged on the first portal frame (41).

8. The numerical control slotting and perforating integrated machine of claim 7, wherein: the second azimuth driving mechanism comprises a second lifting seat (603), the second lifting seat (603) is slidably arranged on the first portal frame (41), a second lifting moving assembly for driving the second lifting seat (603) to lift is arranged on the first portal frame (41), and the lower end of the second lifting seat (603) is slidably connected with the second moving beam (601); the second lifting seat (603) is provided with a horizontal moving component for driving the second moving beam (601) to horizontally move.

9. The numerical control slotting and perforating integrated machine according to claim 8, wherein: drilling equipment (7) are including removing seat (701), remove seat (701) slidable mounting and keep away from one side of horizontal fluting device (6) on first portal frame (41), remove seat (701) and go up slidable mounting and have third lift seat (702), and the below fixed mounting of third lift seat (702) has multiunit package of boring (703).

10. The numerical control slotting and perforating integrated machine according to claim 9, wherein: a moving driving assembly for driving the moving seat (701) to horizontally move is arranged on the first portal frame (41); a third lifting driving component for driving the third lifting seat (702) to lift is arranged on the movable seat (701).