CN223129993U - Numerical control multi-axis gantry machining center - Google Patents

Abstract

The utility model discloses a CNC multi-axis gantry machining center, which relates to the field of gantry machining centers. The utility model comprises a base, a gantry is mounted on the base, a first guide rail is arranged on the base, a cutting assembly is arranged on the gantry, a first workbench and a second workbench are slidably arranged on the first guide rail in sequence, the first workbench and the second workbench can be spliced into an integral workbench after abutting, a first driving assembly for driving the first workbench to move along the first guide rail is arranged on the base, and a second driving assembly for driving the second workbench to move along the first guide rail is arranged on the base. With the cooperation of the first workbench and the second workbench, the first workbench and the second workbench can respectively process small and medium-sized workpieces, and the first workbench and the second workbench can also be combined to process large parts, which effectively improves the adaptability of the gantry machining center to the part size and effectively improves the efficiency of part processing.

Description

Numerical control multi-axis gantry machining center

Technical Field

The utility model relates to the technical field of gantry machining centers, in particular to a numerical control multi-axis gantry machining center.

Background

The gantry machining center is a machining center with the axis of the Z axis of the main shaft perpendicular to the workbench, the whole structure is a large-sized machining center with a portal structure frame formed by double upright posts and top beams, and a cross beam is arranged between the double upright posts, so that the gantry machining center is particularly suitable for machining large-sized workpieces and workpieces with complex shapes.

At present, when a gantry machining center is used for machining workpieces, different types of work tables are required to be equipped for machining the workpieces with different sizes, and therefore adaptability of the gantry machining center to parts with different sizes is poor.

In summary, how to improve the adaptability of the gantry machining center to parts with different sizes is a problem to be solved by those skilled in the art.

Disclosure of utility model

In view of the above, the utility model aims to provide a numerical control multi-axis gantry machining center, which effectively improves the suitability of the gantry machining center for parts with different sizes.

In order to achieve the above object, the present utility model provides the following technical solutions:

The utility model provides a numerical control multiaxis longmen machining center, includes the base, erect the portal frame on the base, be provided with first guide rail on the base, be provided with cutting element on the portal frame, slide in proper order on the first guide rail and be provided with first workstation and second workstation, first workstation with the second workstation can slide to mutual butt state, and can splice into an organic whole workstation at the butt state, be provided with on the base and be used for the drive first workstation is followed first drive assembly that first guide rail removed, be provided with on the base and be used for the drive second workstation is followed the second drive assembly that first guide rail removed.

Preferably, the first driving assembly comprises a first screw rod rotatably arranged on the base and a first rotating motor arranged on the base and used for driving the first screw rod to rotate, and the first screw rod is in threaded connection with the first workbench.

Preferably, the second driving assembly comprises a second screw rod rotatably arranged on the base and a second rotating motor arranged on the base and used for driving the second screw rod to rotate, and the second screw rod is in threaded connection with the second workbench.

Preferably, the first workbench and the second workbench are both rotary workbench;

The portal frame is provided with a second guide rail, a third guide rail is arranged on the second guide rail in a sliding manner, the cutting assembly is arranged on the third guide rail in a sliding manner, and the second guide rail and the third guide rail are arranged in a crisscross manner;

The second guide rail is provided with a third driving assembly for driving the third guide rail to slide along the second guide rail, and the third guide rail is provided with a fourth driving assembly for driving the cutting assembly to slide along the third guide rail.

Preferably, the third driving assembly comprises a third screw rod rotatably arranged on the second guide rail and a third rotating motor arranged on the second guide rail and used for driving the third screw rod to rotate, and the third screw rod is in threaded connection with the third guide rail.

Preferably, the fourth driving assembly comprises a fourth screw rod rotatably arranged on the third guide rail and a fourth rotating motor arranged on the third guide rail and used for driving the fourth screw rod to rotate, the fourth screw rod is connected with a mounting seat in a threaded mode, the mounting seat is in sliding connection with the third guide rail, and the cutting assembly is arranged on the mounting seat.

Preferably, a nitrogen cylinder is arranged between the mounting seat and the third guide rail, and the nitrogen cylinder is used for balancing the inertia effect of the mounting seat.

Preferably, the first workbench comprises a first turntable connecting plate arranged on the first guide rail in a sliding manner, a first servo turntable arranged on the first turntable connecting plate, and a first base plate arranged on the first turntable connecting plate and used for supporting the first servo turntable.

Preferably, the second workbench comprises a second turntable connecting plate arranged on the first guide rail in a sliding manner, a second servo turntable arranged on the second turntable connecting plate, and a second base plate arranged on the second turntable connecting plate and used for supporting the second servo turntable.

Preferably, the base circumference is provided with the protection casing, be provided with the chip groove in the protection casing, the chip groove is used for accomodating the iron fillings after the work piece processing, be provided with screw conveyer in the chip groove, the chip opening has been seted up to one side of protection casing, the protection casing outside is located chip opening department and is provided with the chip removing machine, screw conveyer carry the end with the chip opening is linked together.

The utility model provides a numerical control multi-axis gantry machining center which comprises a base, wherein a gantry frame is erected on the base, a first guide rail is arranged on the base, a cutting assembly is arranged on the gantry frame, a first workbench and a second workbench are sequentially arranged on the first guide rail in a sliding mode, the first workbench and the second workbench can be spliced into an integral workbench after being abutted, a first driving assembly for driving the first workbench to move along the first guide rail is arranged on the base, and a second driving assembly for driving the second workbench to move along the first guide rail is arranged on the base.

According to the numerical control multi-axis gantry machining center, the first workbench and the second workbench are respectively arranged on the first guide rail in a sliding mode, when a small-sized workpiece is required to be machined, the positions of the first workbench and the second workbench are respectively adjusted by the first driving component and the second driving component, machining of the small-sized workpiece is completed, and when a large-sized workpiece is required to be machined, the first workbench and the second workbench are driven to move oppositely by the first driving component and the second driving component, so that the first workbench and the second workbench are spliced into a whole, and machining of the large-sized workpiece is further achieved. The numerical control multi-axis gantry machining center provided by the utility model effectively improves the suitability of the gantry machining center to the size of the part, and simultaneously effectively improves the efficiency of part machining.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required to be used in the embodiments or the description of the prior art will be briefly described below, and it is obvious that the drawings in the following description are only embodiments of the present utility model, and that other drawings can be obtained according to the provided drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic diagram of the overall structure of a numerically controlled multi-axis gantry machining center in this embodiment;

FIG. 2 is a side view of a numerically controlled multi-axis gantry machining center in this embodiment;

fig. 3 is a schematic structural diagram of the numerically controlled multi-axis gantry machining center with a protective cover in this embodiment.

In fig. 1 to 3, reference numerals include:

1. a base; 2, a portal frame, 3, a first guide rail, 4, a cutting component;

5. The device comprises a first workbench, a first turntable connecting plate, a first servo turntable, a first base plate and a first servo turntable, wherein the first workbench is connected with the first turntable connecting plate;

6. The second workbench, 61, a second turntable connecting plate, 62, a second servo turntable, 63, a second backing plate;

7. the first driving assembly, 71, a first lead screw, 72, a first rotating motor;

8. the second driving assembly comprises a second lead screw 81, a second rotating motor 82;

9. 10, a third guide rail;

11. the third driving assembly, 111, the third lead screw, 112, the third rotary motor;

12. A fourth drive assembly; 121, a fourth screw rod, 122, a fourth rotating motor, 123, a mounting seat;

13. 14 parts of nitrogen cylinder, 14 parts of protective cover and 15 parts of chip removing machine.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Unless defined otherwise, technical or scientific terms used in the present disclosure should be given the ordinary meaning as understood by one of ordinary skill in the art to which the present utility model belongs. The terms "first," "second," and the like, as used herein do not denote any order, quantity, or importance. The terms "connected" or "connected," and the like, are not limited to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", etc. are used merely to indicate relative positional relationships, which can be changed accordingly when the absolute position of the object to be described is changed. The embodiment of the utility model discloses a numerical control multi-axis gantry machining center.

The utility model aims at providing a numerical control multi-axis gantry machining center.

Please refer to fig. 1 to 3.

The numerical control multi-axis gantry machining center provided by the utility model comprises a base 1, a gantry 2 is erected on the base 1, a first guide rail 3 is arranged on the base 1, a cutting assembly 4 is arranged on the gantry 2, a first workbench 5 and a second workbench 6 are sequentially arranged on the first guide rail 3 in a sliding manner, the first workbench 5 and the second workbench 6 can slide to be in mutual abutting states, the first workbench and the second workbench 6 can be spliced into an integral workbench in the abutting states, a first driving assembly 7 for driving the first workbench 5 to move along the first guide rail 3 is arranged on the base 1, and a second driving assembly 8 for driving the second workbench 6 to move along the first guide rail 3 is arranged on the base.

The numerical control multi-axis gantry machining center provided by the utility model can drive the first workbench 5 to move along the first guide rail 3 by virtue of the first driving component 7, can drive the second workbench 6 to move along the first guide rail 3 by virtue of the second driving component 8, and can independently move both the first workbench 5 and the second workbench 6, and the workbench is adjusted according to requirements to machine small and medium-sized workpieces. When the large-scale workpiece is required to be processed, the first driving assembly 7 and the second driving assembly 8 are controlled to splice the first workbench 5 and the second workbench 6, so that the large-scale workpiece is processed.

The numerical control multi-axis gantry machining center is matched with the first workbench 5 and the second workbench 6, the first workbench 5 and the second workbench 6 can respectively process small and medium workpieces, and the first workbench 5 and the second workbench 6 can be combined to process large parts, so that the suitability of the gantry machining center to the sizes of the parts is effectively improved, and meanwhile, the efficiency of part machining is effectively improved.

The numerical control multi-axis gantry machining center provided by the utility model is described in more detail below with reference to the accompanying drawings and specific embodiments.

In one embodiment, referring to fig. 1, fig. 1 is a schematic diagram of the overall structure of a numerically controlled multi-axis gantry machining center. The first driving assembly 7 comprises a first screw rod 71 rotatably arranged on the base 1 and a first rotating motor 72 arranged on the base 1 and used for driving the first screw rod 71 to rotate, and the first screw rod 71 is in threaded connection with the first workbench 5.

Specifically, the first rotating motor 72 drives the first screw 71 to rotate, so as to drive the first workbench 5 in threaded connection with the first screw 71 to move along the first guide rail 3, thereby realizing the adjustment movement of the first workbench 5 in the X-axis direction of the gantry machining center, and being convenient for adjusting the position of the first workbench 5 according to the actual machining condition.

On the basis of any one of the above embodiments, referring to fig. 1, the second driving assembly 8 includes a second screw 81 rotatably disposed on the base 1 and a second rotating motor 82 disposed on the base 1 and driving the second screw 81 to rotate, where the second screw 81 is in threaded connection with the second workbench 6.

Specifically, in the same manner as the driving manner of the first workbench 5, the second rotating motor 82 drives the second screw rod 81 to rotate, so as to drive the second workbench 6 in threaded connection with the second screw rod 81 to slide along the first guide rail 3, and further realize the adjustment movement of the second workbench 6 in the X-axis direction of the gantry machining center, so that the position of the second workbench 6 is adjusted according to the actual machining condition.

Further, in some other embodiments, a fifth screw (not shown in the drawings) is rotatably disposed on the base 1, the fifth screw is driven to rotate by a rotation motor in a manner of half forward threads and half reverse threads, wherein the first workbench 5 is screwed on the forward threads of the fifth screw, the second workbench 6 is screwed on the reverse threads of the fifth screw, and the rotation of the fifth screw can drive the first workbench 5 and the second workbench 6 to simultaneously perform opposite or reverse sliding movements along the first guide rail 3, so as to realize synchronous control of the first workbench 5 and the second workbench 6.

On the basis of any one of the above embodiments, referring to fig. 1 and 2, the first working table 5 and the second working table 6 are both rotary working tables, the portal frame 2 is provided with a second guide rail 9, the second guide rail 9 is provided with a third guide rail 10 in a sliding manner, the cutting assembly 4 is arranged on the third guide rail 10 in a sliding manner, the second guide rail 9 and the third guide rail 10 are arranged in a crisscross manner, the second guide rail 9 is provided with a third driving assembly 11 for driving the third guide rail 10 to slide along the second guide rail 9, and the third guide rail 10 is provided with a fourth driving assembly 12 for driving the cutting assembly 4 to slide along the third guide rail 10.

Specifically, the third driving component 11 is matched with the second guide rail 9 to realize the adjustment movement of the cutting component 4 in the Y-axis direction of the multi-axis gantry machining center, the adjustment movement of the cutting component 4 in the Z-axis direction of the multi-axis gantry machining center is realized by means of the matching of the fourth driving component 12 and the third guide rail 10, and the workpiece is machined by matching with a rotary workbench, so that the machining precision of the workpiece is ensured, and meanwhile, the machining efficiency is improved. Meanwhile, the manual universal side milling head can be arranged, one-time clamping and installation can be completed under the condition that the respective workbench rotates, four sides of two small and medium-sized workpieces in the vertical direction are machined at the same time, and the machining efficiency of the workpieces is further improved.

In a specific embodiment provided by the present application, referring to fig. 1 and 2, the third driving assembly 11 includes a third screw 111 rotatably disposed on the second guide rail 9 and a third rotation motor 112 disposed on the second guide rail 9 for driving the third screw 111 to rotate, and the third screw 111 is in threaded connection with the third guide rail 10.

Specifically, the third rotating motor 112 drives the third screw rod 111 to rotate, and the third guide rail 10 in threaded connection with the third screw rod 111 slides along the second guide rail 9 under the drive of the rotation of the third screw rod 111, so that the adjustment movement of the third guide rail 10 in the Y-axis direction of the gantry machining center is realized, and the position of the third guide rail 10 is adjusted according to the actual machining condition.

On the basis of any one of the above embodiments, referring to fig. 1 and 2, the fourth driving assembly 12 includes a fourth screw rod 121 rotatably disposed on the third guide rail 10 and a fourth rotating motor 122 disposed on the third guide rail 10 for driving the fourth screw rod 121 to rotate, a mounting seat 123 is screwed on the fourth screw rod 121, and is slidably connected with the third guide rail 10, and the cutting assembly 4 is disposed on the mounting seat 123.

Specifically, the fourth rotating motor 122 drives the fourth screw rod 121 to rotate, and the mounting seat 123 in threaded connection with the fourth screw rod 121 slides along the third guide rail 10 under the driving of the rotation of the fourth screw rod 121, so that the adjustment movement of the cutting assembly 4 on the mounting seat 123 in the Z-axis direction of the gantry machining center is realized, and the position of the cutting assembly 4 is conveniently adjusted according to the actual machining condition. The fourth rotary motor 122 cooperates with the third rotary motor 112 to achieve multi-angle adjustment of the cutting assembly 4.

On the basis of any one of the above embodiments, referring to fig. 1 and 2, a nitrogen cylinder 13 is provided between the mount 123 and the third rail 10, and the nitrogen cylinder 13 is used to balance the inertial action of the mount 123.

Specifically, the nitrogen cylinder 13 is connected with a nitrogen tank, and an external air source is not needed, so that the nitrogen cylinder 13 plays a role in balancing the inertia of the mounting seat 123 in the process of moving the mounting seat 123 up and down, and the moving precision is improved. Meanwhile, the nitrogen cylinder can be ensured to be an independent system without an external air source, and the external air source is not only provided with air, but also provided with water vapor and other impurities, so that the exhaust cylinder can be corroded.

On the basis of any one of the above embodiments, referring to fig. 1 and 2, the first table 5 includes a first table connecting plate 51 slidably provided on the first rail 3, a first servo turntable 52 provided on the first table connecting plate 51, and a first pad 53 provided on the first table connecting plate 51 for supporting the first servo turntable 52.

Specifically, the first servo turntable 52 realizes the rotation of the first workbench 5, is connected with the first guide rail 3 by virtue of the first turntable connecting plate 51, and is arranged between the first servo turntable 52 and the first turntable connecting plate 51 by virtue of the first base plate 53 in a cushioning manner, so that the stability of the first servo turntable 52 in the rotation process is improved.

On the basis of any one of the above embodiments, referring to fig. 1 and 2, the second table 6 includes a second turntable connecting plate 61 slidably provided on the first rail 3, a second servo turntable 62 provided on the second turntable connecting plate 61, and a second pad 63 provided on the second turntable connecting plate 61 for supporting the second servo turntable 62.

Specifically, similar to the first table 5, the second servo turntable 62 rotates the second table 6, and is connected to the second guide rail 3 by the second turntable connecting plate 61, and is interposed between the second servo turntable 62 and the second turntable connecting plate 61 by the second pad 63, so as to improve the stability of the second servo turntable 62 during rotation.

On the basis of any one of the above embodiments, referring to fig. 1 to 3, a protective cover 14 is circumferentially arranged on the base 1, chip grooves (not shown in the drawings) are arranged in the protective cover 14, the chip grooves are used for accommodating scrap iron after workpiece processing, a screw conveyor (not shown in the drawings) is arranged in the chip grooves, a chip discharge port is formed in one side of the protective cover 14, a chip discharge machine 15 is arranged outside the protective cover 14 at the chip discharge port, and the conveying tail end of the screw conveyor is communicated with the chip discharge port.

In the workpiece machining process, the numerical control multi-axis gantry machining center provided by the embodiment collects scrap iron generated by machining through the scrap grooves, conveys the scrap iron to the scrap opening through the screw conveyor positioned in the scrap grooves, and conveys the scrap iron to the outside of the protective cover 14 through the scrap remover 15 at the scrap opening. The environment-friendly performance of the gantry machining center is effectively improved, and scrap iron generated by machining is convenient to clean in time.

The numerical control multi-axis gantry machining center provided by the utility model is described in detail. The principles and embodiments of the present utility model have been described herein with reference to specific examples, the description of which is intended only to facilitate an understanding of the method of the present utility model and its core ideas. It should be noted that it will be apparent to those skilled in the art that the present utility model may be modified and practiced without departing from the spirit of the present utility model.

Claims (10)

1. The utility model provides a numerical control multiaxis longmen machining center, includes base (1), base (1) are erect on top of the shelf and are had portal frame (2), be provided with first guide rail (3) on base (1), be provided with cutting element (4) on portal frame (2), its characterized in that, first workstation (5) and second workstation (6) are provided with to slide in proper order on first guide rail (3), first workstation (5) with second workstation (6) can slide to mutual butt state, and can splice into an organic whole workstation in the butt state, be provided with on base (1) and be used for the drive first drive assembly (7) that first workstation (5) follow first guide rail (3) removed, be provided with on the base and be used for the drive second drive assembly (8) that second workstation (6) follow first guide rail (3) removed.

2. The numerical control multi-axis gantry machining center according to claim 1, wherein the first driving assembly (7) comprises a first screw (71) rotatably arranged on the base (1) and a first rotating motor (72) arranged on the base (1) and used for driving the first screw (71) to rotate, and the first screw (71) is in threaded connection with the first workbench (5).

3. The numerical control multi-axis gantry machining center according to claim 1, wherein the second driving assembly (8) comprises a second screw rod (81) rotatably arranged on the base (1) and a second rotating motor (82) arranged on the base (1) and used for driving the second screw rod (81) to rotate, and the second screw rod (81) is in threaded connection with the second workbench (6).

4. A numerically controlled multi-axis gantry machining center according to any one of claims 1-3, characterized in that the first (5) and the second (6) tables are both rotary tables;

The cutting device is characterized in that a second guide rail (9) is arranged on the portal frame (2), a third guide rail (10) is arranged on the second guide rail (9) in a sliding mode, the cutting assembly (4) is arranged on the third guide rail (10) in a sliding mode, and the second guide rail (9) and the third guide rail (10) are arranged in a crisscross mode;

The second guide rail (9) is provided with a third driving assembly (11) for driving the third guide rail (10) to slide along the second guide rail (9), and the third guide rail (10) is provided with a fourth driving assembly (12) for driving the cutting assembly (4) to slide along the third guide rail (10).

5. The numerical control multi-axis gantry machining center according to claim 4, wherein the third driving assembly (11) comprises a third screw (111) rotatably arranged on the second guide rail (9) and a third rotating motor (112) arranged on the second guide rail (9) and used for driving the third screw (111) to rotate, and the third screw (111) is in threaded connection with the third guide rail (10).

6. The numerical control multi-axis gantry machining center according to claim 4, wherein the fourth driving assembly (12) comprises a fourth screw rod (121) rotatably arranged on the third guide rail (10) and a fourth rotating motor (122) arranged on the third guide rail (10) and used for driving the fourth screw rod (121) to rotate, a mounting seat (123) is connected to the fourth screw rod (121) in a threaded mode, the mounting seat is slidably connected with the third guide rail (10), and the cutting assembly (4) is arranged on the mounting seat (123).

7. The numerical control multi-axis gantry machining center according to claim 6, wherein a nitrogen cylinder (13) is provided between the mounting base (123) and the third guide rail (10), and the nitrogen cylinder (13) is used for balancing the inertial action of the mounting base (123).

8. The numerical control multi-axis gantry machining center according to claim 4, wherein the first table (5) includes a first table connecting plate (51) slidably disposed on the first guide rail (3), a first servo turntable (52) disposed on the first table connecting plate (51), and a first backing plate (53) disposed on the first table connecting plate (51) for supporting the first servo turntable (52).

9. The numerical control multi-axis gantry machining center according to claim 4, wherein the second table (6) includes a second turntable connecting plate (61) slidably disposed on the first guide rail (3), a second servo turntable (62) disposed on the second turntable connecting plate (61), and a second backing plate (63) disposed on the second turntable connecting plate (61) for supporting the second servo turntable (62).

10. The numerical control multi-axis gantry machining center according to claim 4, wherein a protective cover (14) is circumferentially arranged on the base (1), chip grooves are formed in the protective cover (14) and used for accommodating scrap iron after workpiece machining, screw conveyors are arranged in the chip grooves, chip discharge ports are formed in one sides of the protective cover (14), chip discharge machines (15) are arranged at the positions, located on the chip discharge ports, of the outer portions of the protective cover (14), and conveying tail ends of the screw conveyors are communicated with the chip discharge ports.