CN214687352U - Bridge type cutting and grinding machining center - Google Patents

Abstract

The application relates to a bridge type cutting and grinding machining center which comprises a rack, a portal frame and a driving assembly, wherein the portal frame slides on the rack, and the driving assembly is arranged on the portal frame and connected with the rack; the portal frame is provided with a plurality of adjusting blocks and a moving assembly, and the adjusting blocks are respectively provided with different processing heads; the movement assembly is arranged on the adjusting block and connected with the portal frame. This application has the effect that improves whole machining efficiency.

Description

Bridge type cutting and grinding machining center

Technical Field

The application relates to the technical field of processing equipment, in particular to a bridge type cutting and grinding processing center.

Background

The quartz stone table surface is generally required to be cut and then subjected to edge grinding treatment during processing.

At present, the conventional processing method is to cut the stone slab on a cutting device and then transfer the cut stone slab to an edging device for processing.

With respect to the related art among the above, the inventors consider that the following drawbacks exist: it takes some time to transfer the cut slate to another apparatus, resulting in a longer overall processing time for the slate, thereby reducing efficiency.

SUMMERY OF THE UTILITY MODEL

In order to improve whole machining efficiency, this application provides a bridge type surely grinds machining center.

The application provides a bridge type surely grinds machining center adopts following technical scheme:

a bridge type cutting and grinding machining center comprises a rack, a portal frame and a driving assembly, wherein the portal frame slides on the rack, and the driving assembly is arranged on the portal frame and connected with the rack; the portal frame is provided with a plurality of adjusting blocks and a moving assembly, and the adjusting blocks are respectively provided with different processing heads; the movement assembly is arranged on the adjusting block and connected with the portal frame.

By adopting the technical scheme, the stone slab to be processed is placed on the rack, then one adjusting block moves to the position where the portal frame can process the stone slab under the action of the moving assembly, and the other adjusting blocks move to the end part of the portal frame, so that the influence of processing heads on the other adjusting blocks on the processing of the stone slab is reduced; when the stone slab needs to be processed, the motion assembly is started to drive the adjusting block with the corresponding processing head to move to the stone slab; therefore, the adjusting blocks with the processing heads are arranged on the portal frame in a sliding mode, the time for carrying the stone slabs can be reduced, and the time is saved and the overall processing efficiency is improved.

Optionally, the moving assembly comprises a moving motor, a helical gear and a fixed rack, the moving motor is arranged on the adjusting block, and the helical gear is arranged on the moving motor; the fixed rack is arranged on the portal frame, and the helical gear is meshed with the fixed rack.

By adopting the technical scheme, the motion motor is started, the output shaft of the motion motor drives the bevel gear to rotate, and the bevel gear is meshed with the fixed rack, so that when the bevel gear rotates, the bevel gear can displace relative to the fixed rack, and the bevel gear can drive the adjusting block to slide on the portal frame.

Optionally, a reinforcing mechanism is arranged on the adjusting block, the reinforcing mechanism comprises a connecting plate, a reinforcing rod and an adjusting assembly, a reinforcing groove is formed in the portal frame, the connecting plate slides on the adjusting block, and the reinforcing rod is arranged on the connecting plate and clamped with the reinforcing groove; the adjusting component is arranged on the adjusting block and connected with the connecting plate.

By adopting the technical scheme, after the position of the adjusting block relative to the portal frame is fixed, the adjusting assembly is started, the adjusting assembly drives the connecting plate to approach towards the direction close to the portal frame on the adjusting block, and the reinforcing rod on the connecting plate is clamped with the reinforcing groove on the portal frame; the reinforcing mechanism who sets up can improve the stability of regulating block on the portal frame.

Optionally, the adjusting assembly comprises an adjusting motor, a rotating rod, an adjusting rod and a connecting rod, the adjusting motor is arranged on the adjusting block, the rotating rod is arranged on the adjusting motor, the adjusting rod is arranged on the rotating rod, one end of the connecting rod is hinged to the adjusting rod, and the other end of the connecting rod is hinged to the connecting plate.

Through adopting above-mentioned technical scheme, start adjusting motor, adjusting motor's output shaft drives the bull stick and rotates, and the bull stick will drive the regulation pole and rotate, adjusts the pole and drives the connecting rod motion, and the connecting rod will drive the connecting plate and move on the regulating block.

Optionally, the driving assembly includes a driving motor, a rotating gear and a connecting rack, the driving motor is arranged on the gantry, and the rotating gear is arranged on the driving motor; the connecting rack is arranged on the rack and meshed with the rotating gear.

By adopting the technical scheme, the driving motor is started, the driving motor drives the rotating gear to rotate, and when the rotating gear rotates, the rotating gear can relatively move relative to the connecting rack meshed with the rotating gear; the rotating gear can drive the gantry frame to slide on the rack.

Optionally, the rack is provided with an adsorption assembly, the adsorption assembly comprises an adsorption pump, a sucker and a connecting pipe, and the sucker is arranged on the rack; the sorption pump sets up frame one side, the one end of connecting pipe with the sorption pump is connected and other one end with the sucking disc is connected.

Through adopting above-mentioned technical scheme, place slabstone on the sucking disc, then start the sorption pump, the sorption pump makes and forms the negative pressure between sucking disc and the slabstone, makes the slabstone fix on the sucking disc.

Optionally, a positioning plate is arranged on the frame.

By adopting the technical scheme, the positioning plate can position the stone plate, so that the best position of the stone plate can be fixed by the suction cup; thereby improving the stability of the stone plate fixed by the suction disc.

Optionally, a rotating shaft is arranged on the rack, the positioning plate is arranged on the rotating shaft, a through hole is formed in the rotating shaft, a positioning groove is formed in the rack, and an insertion rod which penetrates through the through hole and is clamped with the positioning groove is arranged on the rotating shaft.

By adopting the technical scheme, when the stone plate on the sucker needs to be positioned, the positioning plate is rotated, the positioning plate drives the third rotating shaft to rotate, and then the inserting rod penetrates through the through hole to be clamped with the positioning groove, so that the operation that an operator always holds the positioning plate is reduced; after the fixed slabstone of sucking disc, make inserted bar and constant head tank part, rotate the locating plate, make the locating plate frame of contradicting, reuse inserted bar passes through the through-hole at last and the constant head tank joint, realizes the fixed of locating plate.

To sum up, this application includes following at least one bridge type surely grinds machining center beneficial technological effect:

1. the adjusting blocks with the processing heads are arranged on the portal frame in a sliding mode, so that the time for carrying the stone slabs can be reduced, the time is saved, and the overall processing efficiency is improved;

2. the reinforcing mechanism who sets up can improve the stability of regulating block on the portal frame.

Drawings

FIG. 1 is a schematic structural diagram of a bridge type cutting and grinding center according to an embodiment of the present disclosure;

FIG. 2 is a schematic structural diagram of a positioning plate according to an embodiment of the present disclosure;

FIG. 3 is an enlarged view of A in FIG. 1;

FIG. 4 is a schematic structural diagram of a motion assembly in an embodiment of the present application;

fig. 5 is a schematic structural diagram of an adjusting assembly in the embodiment of the present application.

Reference numerals: 11. a frame; 12. a gantry; 121. a reinforcing groove; 2. a drive assembly; 21. a drive motor; 22. a rotating gear; 23. connecting the racks; 3. an adjusting block; 4. a motion assembly; 41. a motion motor; 42. a helical gear; 43. fixing a rack; 5. a reinforcement mechanism; 51. a connecting plate; 52. a reinforcing rod; 53. an adjustment assembly; 531. adjusting the motor; 532. a rotating rod; 533. adjusting a rod; 534. a connecting rod; 6. an adsorption component; 61. an adsorption pump; 62. a suction cup; 63. a connecting pipe; 7. positioning a plate; 81. a connecting seat; 82. a bolt; 83. a rotating shaft; 831. a through hole; 84. and (4) inserting the rod.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

The embodiment of the application discloses bridge type cutting and grinding machining center.

Referring to fig. 1, the bridge type cutting and grinding machining center includes a frame 11, and an adsorption assembly 6 and a positioning plate 7 are disposed on the frame 11; the gantry 12 is connected to the rack 11 in a sliding manner, and the driving assembly 2 connected with the gantry 12 is arranged on the rack 11; two adjusting blocks 3 are connected to the portal frame 12 in a sliding mode, and moving assemblies 4 connected with the portal frame 12 are arranged on the two adjusting blocks 3.

The adsorption component 6 comprises a suction cup 62 fixedly connected to the frame 11; an adsorption pump 61 is provided on one side of the frame 11, and a connection pipe 63 connected to the suction cup 62 is connected to the adsorption pump 61. The stone plate to be processed is placed on the suction cups 62, the suction pump 61 is started, negative pressure is formed on the suction cups 62, and the stone plate is sucked on the suction cups 62, so that the stone plate is fixed.

Referring to fig. 1 and 2, a connecting seat 81 is arranged on one side of the suction cup 62, the connecting seat 81 is connected to the frame 11 through a bolt 82, a rotating shaft 83 is rotatably connected to the connecting seat 81, a through hole 831 is formed in the rotating shaft 83, and the axis of the through hole 831 is perpendicular to the axis of the rotating shaft 83; the connecting seat 81 is provided with a positioning groove, and the rotating shaft 83 is provided with an inserting rod 84 which passes through the through hole 831 and is clamped with the positioning groove. The rotating shaft 83 is fixedly connected with a positioning plate 7.

When the stone plate needs to be fixed by the suction cup 62, the positioning plate 7 is rotated to make the positioning plate 7 perpendicular to the frame 11, and then the insertion rod 84 penetrates through the through hole 831 on the rotating shaft 83 to be clamped with the positioning groove on the connecting seat 81, so that the positioning plate 7 is fixed. Then, the stone plate is abutted against the positioning plate 7, so that the position of the stone plate is fixed, and then the adsorption pump 61 is started to fix the stone plate.

Referring to fig. 1 and 3, the driving assembly 2 includes a driving motor 21 fixedly connected to the gantry 12, and a rotating gear 22 is keyed on an output shaft of the driving motor 21; a connecting rack 23 engaged with the rotating gear 22 is fixedly connected to the frame 11.

The driving motor 21 is started and the output shaft thereof drives the rotating gear 22 to rotate, because the rotating gear 22 is meshed with the connecting rack 23, when the rotating gear 22 rotates, the rotating gear 22 will move relative to the connecting rack 23, and the driving motor 21 will drive the gantry 12 to move on the frame 11.

Referring to fig. 1 and 4, the moving assembly 4 includes a moving motor 41 fixedly connected to the adjusting block 3, and a helical gear 42 is keyed on an output of the moving motor 41; a fixed rack 43 engaged with the helical gear 42 is fixedly connected to the gantry 12.

The moving motor 41 is started and its output shaft drives the rotating bevel gear 42, because the bevel gear 42 is meshed with the fixed rack gear 43, when the bevel gear 42 rotates, the bevel gear 42 will move relative to the fixed rack gear 43, and the moving motor 41 will drive the adjusting block 3 to move on the portal frame 12.

Referring to fig. 4 and 5, a reinforcing groove 121 is formed in the portal frame 12, a communicating cavity is formed in the adjusting block 3, a reinforcing mechanism 5 is arranged on the adjusting block 3, the reinforcing mechanism 5 comprises a connecting plate 51 connected in the communicating cavity in a sliding manner, and a reinforcing rod 52 connected with the reinforcing groove 121 in a clamping manner is fixedly connected to one side of the connecting plate 51 facing the adjusting block 3. An adjusting component 53 is arranged on the adjusting block 3, and the adjusting component 53 comprises an adjusting motor 531 fixedly connected to the side wall of the communicating cavity; two rotating rods 532 are arranged in the adjusting block 3, one of the rotating rods 532 is connected to an output shaft of the adjusting motor 531, one end of the rotating rod 532 far away from the adjusting motor 531 is fixedly connected with an adjusting rod 533, and the adjusting rod 533 is U-shaped; one end of the other rotating rod 532 is rotatably connected to the side wall of the communicating cavity, the other end of the other rotating rod 532 is connected with one end of the adjusting rod 533 far away from the adjusting motor 531, and the axes of the two rotating rods 532 are overlapped; the adjusting rod 533 is hinged with a connecting rod 534 hinged with the connecting plate 51.

After the position of the adjusting block 3 is determined, the adjusting motor 531 is started, the output shaft of the adjusting motor drives the rotating rod 532 to rotate, the rotating rod 532 drives the adjusting rod 533 to rotate, the adjusting rod 533 will drive the connecting rod 534 to move, the connecting rod 534 drives the connecting rod to move in the direction close to the portal frame 12 in the communicating cavity, and the reinforcing rod 52 on the connecting plate 51 is clamped with the reinforcing groove 121 on the portal frame 12.

Referring to fig. 1 and 4, processing heads are arranged on the two adjusting blocks 3, wherein the processing heads are connected to the adjusting blocks 3 in a sliding mode through a motor screw rod structure, one of the processing heads is a cutting head, and the other processing head is an edging head.

The motors in this embodiment are all three-phase asynchronous motors.

The implementation principle of the bridge type cutting and grinding machining center in the embodiment of the application is as follows: placing the stone plate on the suction cup 62, fixing the position of the positioning plate 7, adjusting the position of the stone plate, and then starting the adsorption pump 61 to fix the stone plate on the suction cup 62; finally, the positioning plate 7 is rotated to make the positioning plate 7 parallel to the frame 11.

Then, starting a driving motor 21 and adjusting the position of the portal frame 12; starting a driving motor 41, enabling one adjusting block 3 to be located at the accessory of the stone slab and processing the stone slab, and enabling the other adjusting block 3 to move to one end of the portal frame 12; after the position of the adjusting block 3 is determined, the adjusting motor 531 is started, so that the reinforcing rod 52 is clamped with the reinforcing groove 121 on the portal frame 12, and the adjusting block 3 is reinforced.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. A bridge type cutting and grinding machining center comprises a rack (11), a portal frame (12) and a driving assembly (2), wherein the portal frame (12) slides on the rack (11), and the driving assembly (2) is arranged on the portal frame (12) and connected with the rack (11); the gantry is characterized in that a plurality of adjusting blocks (3) and a moving assembly (4) are arranged on the gantry (12), and different machining heads are respectively arranged on the adjusting blocks (3); the moving assembly (4) is arranged on the adjusting block (3) and is connected with the portal frame (12).

2. A bridge type chopping and grinding machining center according to claim 1, characterized in that the moving assembly (4) comprises a moving motor (41), a bevel gear (42) and a fixed rack (43), the moving motor (41) is arranged on the adjusting block (3), the bevel gear (42) is arranged on the moving motor (41); the fixed rack (43) is arranged on the portal frame (12), and the bevel gear (42) is meshed with the fixed rack (43).

3. The bridge type cutting and grinding machining center according to claim 1, wherein a reinforcing mechanism (5) is arranged on the adjusting block (3), the reinforcing mechanism (5) comprises a connecting plate (51), a reinforcing rod (52) and an adjusting assembly (53), a reinforcing groove (121) is formed in the portal frame (12), the connecting plate (51) slides on the adjusting block (3), and the reinforcing rod (52) is arranged on the connecting plate (51) and clamped with the reinforcing groove (121); the adjusting component (53) is arranged on the adjusting block (3) and connected with the connecting plate (51).

4. A bridge type chopping and grinding machining center according to claim 3, characterized in that the adjusting assembly (53) comprises an adjusting motor (531), a rotating rod (532), an adjusting rod (533) and a connecting rod (534), the adjusting motor (531) is arranged on the adjusting block (3), the rotating rod (532) is arranged on the adjusting motor (531), the adjusting rod (533) is arranged on the rotating rod (532), one end of the connecting rod (534) is hinged on the adjusting rod (533) and the other end is hinged on the connecting plate (51).

5. A bridge type chopping and grinding machining center according to claim 1, characterized in that the driving assembly (2) comprises a driving motor (21), a rotating gear (22) and a connecting rack (23), the driving motor (21) is arranged on the gantry (12), and the rotating gear (22) is arranged on the driving motor (21); the connecting rack (23) is arranged on the rack (11) and meshed with the rotating gear (22).

6. A bridge type cutting and grinding machining center according to claim 1, characterized in that the frame (11) is provided with a suction assembly (6), the suction assembly (6) comprises a suction pump (61), a suction cup (62) and a connecting pipe (63), the suction cup (62) is arranged on the frame (11); the adsorption pump (61) is arranged on one side of the rack (11), one end of the connecting pipe (63) is connected with the adsorption pump (61), and the other end of the connecting pipe is connected with the sucker (62).

7. A bridge cutting and grinding machining center according to claim 6, characterized in that the frame (11) is provided with a positioning plate (7).

8. The bridge type cutting and grinding machining center according to claim 7, wherein a rotating shaft (83) is arranged on the machine frame (11), the positioning plate (7) is arranged on the rotating shaft (83), a through hole (831) is formed in the rotating shaft (83), a positioning groove is formed in the machine frame (11), and an insertion rod (84) which penetrates through the through hole (831) and is clamped with the positioning groove is arranged on the rotating shaft (83).

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