CN212266255U - Horizontal stone material processing equipment of bull - Google Patents

Abstract

The utility model relates to a horizontal stone material processing equipment of bull, including frame, crossbeam, at least one sideslip seat, lift seat, work piece platform and processingequipment, the crossbeam can be followed longitudinal movement ground and assembled in the frame, and the sideslip seat can be followed lateral movement ground and assembled in the crossbeam, should transversely be crossbeam length direction, and the seat that goes up and down can be assembled in the sideslip seat relatively sideslip seat, and processingequipment assembles in the seat that goes up and down. The processing device is a saw blade processing device or an engraving processing device. Each transverse moving seat is correspondingly provided with two lifting seats, and the two lifting seats are respectively arranged on two sides of the corresponding transverse moving seat in the longitudinal direction. Each lifting seat is provided with one processing device, and the processing devices are fixedly arranged on the lifting seats. The utility model discloses set up processingequipment's structure respectively in the vertical both sides of sideslip seat, can make whole sideslip seat center more approach in crossbeam place position, help lifting means's stability.

Description

Horizontal stone material processing equipment of bull

Technical Field

The utility model relates to a stone material processing equipment field, concretely relates to horizontal stone material processing equipment of bull.

Background

The existing processing of the columnar stone workpiece has two types, namely, the columnar stone workpiece is cut through a saw blade processing device, and the columnar stone workpiece is carved through a carving tool bit driven by an electric spindle. The two types of processing modes can be independently processed, and can also be firstly profiled by a saw blade and then carved. And the realization of current above-mentioned processing mode is separately gone on through two independent equipment mostly, but large-scale column stone material work piece is bulky, weight is big mostly, if want the advantage of the above-mentioned two kinds of processing modes of combination, just need transport in two equipment, wastes time and energy and damage stone material work piece, workshop equipment or even injure people's risk in addition.

Chinese patents 201220378019.6, 201220377937.7 disclose a combination of a carving bit and a saw blade, but the above solutions all have the following disadvantages: firstly, the working characteristics of the saw blade processing device and the carving processing device are different, and the saw blade processing device and the carving processing device are assembled together and are easy to influence each other; in particular, in the process of processing a columnar stone workpiece by using a saw blade processing device, particularly a large stone workpiece, in order to ensure the processing efficiency, the processing speed of a saw blade needs to be increased, which also brings large and continuous reaction force to the processing device, and because the stone processing device has the characteristics of impact caused by increased local hardness due to the influence of trace substances contained in the stone processing device, more dust in the stone processing and the like, the saw blade processing device has large impact on the assembly position, but the requirement on the processing precision is smaller than that of a carving tool bit; the contact surface of the engraving tool bit of the engraving device and the stone workpiece is small, the corresponding reaction force is small, and the requirements on the machining precision and the working stability are high. Secondly, in the above scheme, even the saw bit passes through the structure protection such as cover and also can cause influences such as splash to its periphery, with the scheme that carve the cutter head and saw bit near setting, the saw bit influences easily even damages the sculpture cutter head.

To solve the above problems, the proposal disclosed in chinese patent No. 201720663333.1 comes from the fact that the operating characteristics of water jet cutting are close to those of the carving tool bit, the cutting tool bit and the carving tool bit are assembled on the same seat body, and the saw blade processing device is independently assembled on the same seat body. Although this scheme can solve above-mentioned problem, in this scheme working process, a plurality of pedestals are used for processing a stone material work piece, inevitably, many pedestal assembly structure is more complicated, control is more loaded down with trivial details, and idle processingequipment and the pedestal of assembly thereof need occupation space, under the same conditions, the volume of equipment has been increased, and stone material processing equipment volume itself just is great and the dead weight is heavier, further increase again, it brings the equipment production, transport, the influence that occupies the increase of workshop position etc. when using is big, influence or even loses the market competitiveness of equipment.

Disclosure of Invention

The utility model provides a horizontal stone material processing equipment of bull to solve above-mentioned problem.

The utility model adopts the following technical scheme:

the utility model provides a horizontal stone material processing equipment of bull, which comprises a frame, the crossbeam, at least one sideslip seat, the seat goes up and down, workpiece table and processingequipment, the crossbeam can be assembled in the frame along longitudinal movement ground, the sideslip seat can be assembled in the crossbeam along lateral movement ground, should transversely be crossbeam length direction, should vertically be in the horizontal plane with this horizontal vertically direction, the seat goes up and down to assemble in the sideslip seat relatively sideslip seat, processingequipment assembles in the seat goes up and down, the workpiece table is located the crossbeam below and is used for placing the stone material work piece, processingequipment is used for processing the stone material work piece. The processing device is a saw blade processing device or an engraving processing device. Each transverse moving seat is correspondingly provided with two lifting seats, and the two lifting seats are respectively arranged on two sides of the corresponding transverse moving seat in the longitudinal direction. Each lifting seat is provided with one processing device, and the processing devices are fixedly arranged on the side surface of one side of the lifting seat, which deviates from the transverse moving seat where the lifting seat is arranged.

From the above description of the structure of the present invention, compared with the prior art, the present invention has the following advantages:

one of them, the utility model discloses a be located vertical ascending both sides at the sideslip seat and set up the lift seat respectively, then at the structure of lift seat assembly processingequipment, realized setting up two processingequipment simultaneously at same equipment to reduce like stone material work piece transports etc. and then promote machining efficiency. If the stone workpiece needs to be firstly modeled by a saw blade processing device and then carved by a carving processing device, the stone workpiece can be processed step by a transverse moving seat with two processing devices after being placed on a workpiece table at one time. Further, the utility model discloses locate same sideslip seat with two processingequipment, and then also avoided assembling a plurality of processingequipment that are used for processing same stone material work piece through a plurality of sideslip seats and the structure that brings is complicated, control loaded down with trivial details, equipment volume increase scheduling problem.

Two, the utility model discloses a be located vertical ascending both sides at the sideslip seat and set up the lift seat respectively, then at lift seat assembly processingequipment's structure, because two mutual influence between two processingequipment need transmit two lift seats, a sideslip seat, a crossbeam. Therefore the utility model discloses the structure sets up saw bit processingequipment and sculpture processingequipment's the condition simultaneously at a cooperation sideslip seat under, the different and mutual influence that bring of the speciality of saw bit processingequipment and sculpture processingequipment work will be controlled to the level that can accept to the assembly structure that saw bit processingequipment and sculpture processingequipment essence deviate from mutually also can prevent to add the condition that spatter and influence sculpture processingequipment such as dust, grit, sewage if the saw bit.

Thirdly, the utility model discloses set up processingequipment's structure respectively in the vertical both sides of sideslip seat, can make whole sideslip seat center more approach to in crossbeam place position, help lifting means's stability. And the torsion force direction that the processingequipment during operation of sideslip seat both sides was applyed to sideslip seat and crossbeam is opposite, and this structure can avoid sideslip seat and crossbeam to receive the unidirectional action influence for a long time and wear promptly, helps promoting product stability and durability.

Further:

each transverse moving seat is correspondingly provided with one workpiece table. The work piece table is used for placing stone work pieces by jacking the two end faces of the stone work pieces which are horizontally placed. The stone work pieces are arranged along the longitudinal extension after lying, and the extension direction of the stone work pieces is the extension direction of the stone work pieces from one supported surface to the other supported surface.

Each above-mentioned work piece platform all includes a initiative pedestal, a driven pedestal and a set of pedestal slide rail, and the pedestal slide rail sets up along above-mentioned longitudinal extension, and initiative pedestal and driven pedestal can be followed the pedestal slide rail respectively and movably locate on the pedestal slide rail. The driving pedestal is additionally provided with a driving propping part and a workpiece driving mechanism, the driving propping part is rotatably arranged on the driving pedestal, and the workpiece driving mechanism is assembled on the driving pedestal and is used for driving the driving propping part to rotate. The driven pedestal is additionally provided with a driven propping part and an adjusting handle wheel, the driven propping part is rotatably assembled on the driven pedestal, and the adjusting handle wheel is used for driving the driven propping part to move along the longitudinal direction. The driving supporting part and the driven supporting part are arranged oppositely.

The driving pedestal is also provided with a driving rotating shaft, and the driving rotating shaft is rotatably assembled at the top of the driving pedestal through at least two bearings. The driving propping part is assembled at one end part of the driving rotating shaft, and the workpiece driving mechanism is in transmission connection with the other end part of the driving rotating shaft. The driven pedestal is also provided with an adjusting seat and a driven rotating shaft, the adjusting seat can be assembled on the top of the driven pedestal along the longitudinal movement, the adjusting seat is driven by the adjusting handle to move, and the driven rotating shaft can be rotatably assembled on the top of the adjusting seat through at least two bearings. The driven supporting part is assembled at one end part of the driven rotating shaft facing the driving supporting part. The driving supporting part and the driven supporting part can be structures such as thimbles, multi-jaw chucks and the like or a combination of the structures, which are common in the field.

It is right by the aforesaid the utility model discloses it can be known to the description of the structure of further scheme, compare with prior art, the utility model discloses a workpiece table is through the setting of the structure of adjustment seat, compares in the structure that current direct set up the driven portion of holding of pushing up of screw rod pushing mechanism adjustment on driven pedestal top, the utility model discloses a driven spindle can be longer, and its arm of force is bigger promptly, and the utility model discloses the stone material work piece of processing is general bulky big weight, therefore the bigger structure of this arm of force can ensure workpiece table's stability, especially under the state of engraving device work, can greatly promote product quality, equipment operating stability and greatly reduce the fault rate of equipment. And the structure with larger force arm can also improve the durability of the driven pedestal.

Just the utility model discloses a stone material work piece in the work piece platform is along longitudinal extension, can make the processingequipment of a plurality of sideslip seat assemblies on the crossbeam correspond synchronous working, the machining efficiency of optimizing apparatus.

The rack comprises two side racks and a connecting rack, the two side racks are arranged in parallel along the longitudinal extension direction, and the connecting rack is connected with the bottoms of the two side racks. The workpiece table is arranged on the connecting rack. The end parts of the two ends of the cross beam are respectively assembled on the top surfaces of the two side frames.

The side frame is additionally provided with a control box and an operation table, the control box is arranged in the side frame, and the operation table is assembled on the outer edge of the side frame. The side surface of the side frame, which is deviated from one side of the connecting frame, is provided with a box door, and the box door is communicated with the control box. The operating platform is assembled on the side edge of the side frame through a swing arm, the swing arm extends along the horizontal direction, the bottom surface of the operating platform is rotatably assembled at the end part of one end of the swing arm, the end part of the other end of the swing arm is assembled on the side edge of the side frame through a swing arm seat, and the swing arm is rotatably assembled with the swing arm seat.

The transverse beam can be longitudinally moved and assembled through a longitudinal moving mechanism. The longitudinal moving mechanism comprises a longitudinal moving guide rail, a longitudinal moving rack, a longitudinal moving slide block and a longitudinal moving motor, wherein the longitudinal moving guide rail and the longitudinal moving rack are arranged along the longitudinal extension, the longitudinal moving guide rail and the longitudinal moving rack are divided into two groups, the two groups of longitudinal moving guide rail and longitudinal moving rack are respectively arranged at the tops of the two side frames, the longitudinal moving slide block and the longitudinal moving motor are divided into two groups, the two groups of longitudinal moving slide block and the longitudinal moving motor are respectively arranged at two ends of a cross beam, the longitudinal moving slide block positioned at the same side is arranged on the longitudinal moving guide rail in a sliding manner, each longitudinal moving motor is additionally provided with a longitudinal moving gear, and the longitudinal moving gear positioned at the same side is connected with. Each lifting seat can be lifted and assembled relative to the transverse moving seat through a lifting mechanism. Each lifting mechanism comprises a lifting guide rail, a lifting slider, a lifting screw rod, a lifting motor and a lifting nut, wherein the lifting slider and the lifting nut are fixedly assembled on one side of the lifting seat facing the transverse moving seat where the lifting seat is located, the lifting guide rail, the lifting screw rod and the lifting motor are assembled on one side of the transverse moving seat facing the lifting seat, the lifting guide rail and the lifting screw rod extend along the vertical direction, the lifting motor is used for driving the lifting screw rod to rotate, the lifting slider is slidably arranged on the lifting guide rail, and the lifting nut and the lifting screw rod are sleeved outside the lifting screw rod in a matched mode.

The cross section of the beam is arranged in a square shape. The main body of the transverse moving seat is sleeved outside the beam in a square frame shape, the square frame-shaped structure of the main body of the transverse moving seat is a square frame-shaped structure enclosed by four flat plates arranged on the periphery of the beam, and the side plates at two sides of the transverse moving seat provided with the lifting seat are arranged to protrude out of the main body of the transverse moving seat in a vertically extending manner. The two processing devices positioned at two sides of the same transverse moving seat are respectively one saw blade processing device and one engraving processing device. The engraving device comprises an electric spindle and an engraving tool bit, wherein the electric spindle is used for driving the engraving tool bit to rotate. The saw blade processing device comprises a processing saw blade and a processing motor, wherein the processing saw blade and the processing motor are assembled on the lifting seat through an installation arm respectively, and the processing motor is arranged above the processing saw blade. The end parts of the mounting arms are fixedly assembled on the side surface of the lifting seat, and the processing motor and the processing saw blade are respectively assembled on the side surface of the mounting arm where the processing motor and the processing saw blade are respectively positioned on the transverse direction. The lifting seat provided with the saw blade machining device is in a plate-shaped arrangement, two mounting arms arranged on the lifting seat are respectively arranged at the upper end and the lower end of the lifting seat and are respectively adjacent to the side edges of the two sides of the lifting seat in the width direction, and the machining motor and the machining saw blade are respectively assembled on one side, opposite to the two mounting arms.

As can be seen from the above description of the structure of the further aspect of the present invention, compared with the prior art, the present invention has the following advantages:

the utility model discloses a crossbeam cooperation square frame structure of square cross-section is the sideslip seat of main part, and the whole rigidity of sideslip seat is stronger and its and crossbeam cooperation are more firm, and then lifting means's stability to because the sculpture processingequipment during operation needs better accurate degree, the accurate degree of equipment operation can be ensured to the sideslip seat of stronger rigidity, and then can ensure the operation of sculpture processingequipment and the product quality of lifting means output.

In prior art, the poor stability of processingequipment mounted position (specifically be sideslip seat structural rigidity, structural stability poor), under equipment off-working state, because factors such as the dead weight of each part self of equipment, it is difficult to reachd through the inspection, and under equipment operating condition, the noise that produces during stone material work piece adds man-hour also makes this problem can't show, promptly the utility model discloses a scheme just is difficult to think out from the discovery of problem.

The transverse moving seat can be assembled along the transverse moving direction through a transverse moving mechanism. The transverse moving mechanism comprises a transverse moving guide rail, a transverse moving rack, a transverse moving slide block and a transverse moving motor, wherein the transverse moving guide rail and the transverse moving rack are arranged in a transverse extending mode, and the transverse moving guide rail and the transverse moving rack are respectively arranged on at least one of four outer surfaces of the transverse beam extending in the transverse direction. Each transverse moving seat is additionally provided with the transverse moving slide block and the transverse moving motor, the transverse moving slide block is arranged corresponding to the transverse moving guide rail and is arranged on the inner side surface of the square frame-shaped structure of the transverse moving seat, and the transverse moving motor is fixedly assembled on the transverse moving seat where the transverse moving slide block is arranged. Each traverse motor is additionally provided with a traverse gear which is meshed with the traverse rack.

The three transverse guide rails are respectively arranged on the top surface of the cross beam and the two side surfaces of the cross beam in the longitudinal direction. The transverse rack is arranged on the top surface of the beam. The transverse moving seat is provided with two side plates of the lifting seat which extend upwards along the vertical direction, and the transverse moving motor is arranged between the extending ends of the two side plates of the transverse moving seat.

As can be seen from the above description of the structure of the further aspect of the present invention, compared with the prior art, the present invention has the following advantages:

the utility model discloses a crossbeam top surface, both sides bottom surface even all can be used to set up the structure of sideslip guide rail under the state of processingequipment work the utility model discloses a sideslip guide rail and the sideslip slider synergism of contact surface are down in the time of the guarantee of sideslip seat structural rigidity, and antitorque commentaries on classics ability, shock resistance of sideslip seat are stronger, consequently the utility model discloses an equipment operation is more stable, and is same, and stronger structural rigidity and better assembly stability also can ensure the accurate degree of equipment operation.

And the sideslip motor is arranged on the structure between the extending ends of the side plates on the two sides of the sideslip seat, so that the sideslip motor and the sideslip gear can be protected in the environment of high dust and gravel during the operation of the stone machining equipment, the problems of damage to the sideslip mechanism, reduction of the running stability and the accuracy degree of the sideslip mechanism and the like caused by poor working environment are solved.

Drawings

Fig. 1 is a schematic structural view of the multi-head horizontal stone processing equipment of the present invention.

Fig. 2 is the schematic view of the exploded structure of the multi-head horizontal stone processing equipment of the present invention.

Fig. 3 is an enlarged structural diagram of a part a in fig. 2.

Fig. 4 is an enlarged structural diagram of a part B in fig. 2.

Fig. 5 is a schematic view of the assembly structure of the transverse moving seat assembly part of the transverse moving mechanism of the present invention.

Fig. 6 is the schematic structural diagram of the workpiece table after placing the stone workpiece.

Detailed Description

The following describes embodiments of the present invention with reference to the drawings.

Referring to fig. 1 and 2, the multi-head horizontal stone machining device comprises a rack, a cross beam 2, at least one transverse moving seat 3, a lifting seat 4, a workpiece table 5 and a machining device, wherein the cross beam 2 can be assembled on the rack in a longitudinally moving mode, the transverse moving seat 3 can be assembled on the cross beam 2 in a transversely moving mode, the lifting seat 4 can be assembled on the transverse moving seat 3 in a lifting mode relative to the transverse moving seat 3, the machining device is assembled on the lifting seat 4, the workpiece table 5 is arranged below the cross beam 2 and used for placing a stone workpiece 50, and the machining device is used for machining the stone workpiece 50. The transverse direction is the length direction of the cross beam 2, the longitudinal direction is the direction perpendicular to the transverse direction in the horizontal plane, and the transverse direction and the longitudinal direction are defined as two mutually perpendicular directions for convenience of description, and the definition is limited to relative relation and is not limited to absolute meanings of the word. The processing device is a saw blade processing device 61 or an engraving device 62. Each of the traverse seats 3 is correspondingly provided with two of the lifting seats 4, and the two lifting seats 4 are respectively arranged at two sides of the corresponding traverse seat 3 in the longitudinal direction. Each lifting seat 4 is provided with one processing device, and the processing device is fixedly arranged on the side surface of one side of the lifting seat 4, which deviates from the transverse moving seat 3 where the lifting seat is arranged.

With continued reference to fig. 1 and 2, in the above structure, one workpiece stage 5 is a basic station, and according to actual needs, one traverse seat 3 may be provided, or a plurality of traverse seats 3 may be provided to improve the processing efficiency, and this embodiment adopts a structure in which two traverse seats 3 correspond to two workpiece stages 5. In which the two traverse seats 3 are identical in structure, so that fig. 2 is an exploded view of only one of the traverse seats 3 and the other structures mounted on the traverse seat 3. The two processing devices on the same transverse moving seat 3 can be selected according to the requirements in the two processing device structures, and even the processing modes of other structures can be selected. In the present embodiment, in order to better realize the combination of the processing characteristics of the two processing devices, specifically, the two processing devices located on both sides of the same traverse table 3 are respectively one saw blade processing device 61 and one engraving device 62.

Referring to fig. 1 and 6, the work table 5 is used to place the stone work 50 by supporting both end surfaces of the stone work 50 lying on the work table. The stone work pieces 50 are laid and then extend in the longitudinal direction, and the extending direction of the stone work pieces 50 is the extending direction in which the stone work pieces 50 extend from one supported surface to the other supported surface. Each of the workpiece tables 5 includes a driving table base 51, a driven table base 52 and a set of table base slide rails 53, the table base slide rails 53 extend along the longitudinal direction, and the driving table base 51 and the driven table base 52 are respectively movably disposed on the table base slide rails 53 along the table base slide rails 53. The active pedestal 51 is provided with an active propping part 511, an active rotating shaft 512 and a workpiece driving mechanism 513, wherein the active propping part 511 is rotatably arranged on the active pedestal 51, and the workpiece driving mechanism 513 is assembled on the active pedestal 51 and is used for driving the active propping part 511 to rotate. The driving shaft 512 is rotatably mounted on the top of the driving stage 51 by at least two bearings. The driving supporting portion 511 is assembled at one end of the driving shaft 512, and the workpiece driving mechanism 513 is connected to the other end of the driving shaft 512 in a transmission manner. The workpiece drive mechanism 513 may be a drive mechanism such as a conventional motor driven variable speed assembly.

With continued reference to fig. 1 and 6, the driven base 52 is provided with a driven abutting portion 521, an adjusting base 522, a driven rotating shaft 523 and an adjusting handle wheel 524, the driven abutting portion 521 is rotatably mounted on the driven base 52, and the adjusting handle wheel 524 is used for driving the driven abutting portion 521 to move along the longitudinal direction. The driving abutting portion 511 is disposed opposite to the driven abutting portion 521. The adjustment base 522 is movably mounted on the top of the driven base 52 along the longitudinal direction, the adjustment base 522 is driven by the adjustment handle wheel 524, and the driven rotation shaft 523 is rotatably mounted on the top of the adjustment base 522 through at least two bearings. The driven abutting portion 521 is attached to an end of the driven rotating shaft 523 facing the driving abutting portion 511. The driving supporting portion 511 and the driven supporting portion 521 can be a thimble, a multi-jaw chuck, or a combination thereof, which are commonly known in the art. The driving pedestal 51 and the driven pedestal 52 are both fixed relative to the pedestal slide rail 53 (e.g., pins are inserted) when the stone workpiece 50 is placed therein, and the adjustment handle wheel 524 can further drive the driven supporting portion 521 to move toward the driving supporting portion 511, thereby fixing the stone workpiece 50.

Referring to fig. 1, the frame includes two side frames 11 and a connecting frame 12, the two side frames 11 are disposed in parallel along the longitudinal direction, and the connecting frame 12 is disposed to connect the bottoms of the two side frames 11. The work table 5 is provided on the connecting frame 12. The ends of the two ends of the beam 2 are respectively assembled on the top surfaces of the two side frames 11. The side frame 11 is attached with a control box and an operation table 111, the control box is arranged in the side frame 11, and the operation table 111 is assembled on the outer edge of the side frame 11. The side surface of the side frame 11, which is far away from the connecting frame 12, is provided with a box door, and the box door is communicated with the control box. The operation table 111 is assembled on the side edge of the side frame 11 through a swing arm, the swing arm extends along the horizontal direction, the bottom surface of the operation table 111 is rotatably assembled on the end part of one end of the swing arm, the end part of the other end of the swing arm is assembled on the side edge of the side frame 11 through a swing arm seat, and the swing arm is rotatably assembled on the swing arm seat.

Referring to fig. 1, 2 and 4, the beam 2 is longitudinally movably assembled by a longitudinal moving mechanism. The longitudinal moving mechanism comprises a longitudinal moving guide rail 71, a longitudinal moving rack 72, a longitudinal moving slide block 73 and a longitudinal moving motor 74, wherein the longitudinal moving guide rail 71 and the longitudinal moving rack 72 are longitudinally extended, the longitudinal moving guide rail 71 and the longitudinal moving rack 72 are divided into two groups, the two groups of longitudinal moving guide rails 71 and the longitudinal moving rack 72 are respectively arranged at the tops of the two side frames 11, the longitudinal moving slide block 73 and the longitudinal moving motor 74 are divided into two groups, the two groups of longitudinal moving slide blocks 73 and the longitudinal moving motor 74 are respectively arranged at two ends of the cross beam 2, the longitudinal moving slide blocks 73 positioned at the same side are slidably arranged on the longitudinal moving guide rail 71, each longitudinal moving motor 74 is additionally provided with a longitudinal moving gear 741, and the longitudinal moving gear 741 positioned at the same side is meshed with the longitudinal moving rack 72 and connected with the longitudinal. The two longitudinal movement motors 74 located at both ends of the beam 2 are servo motors that operate synchronously.

Referring to fig. 1, 2 and 3, each of the lifting seats 4 is vertically assembled with respect to the traverse seat 3 by a lifting mechanism. Each lifting mechanism comprises a lifting guide rail 81, a lifting slide block 82, a lifting screw rod 83, a lifting motor 84 and a lifting nut 85, wherein the lifting slide block 82 and the lifting nut 85 are fixedly assembled on one side of the lifting seat 4 facing the transverse moving seat 3 where the lifting seat is located, the lifting guide rail 81, the lifting screw rod 83 and the lifting motor 84 are assembled on one side of the transverse moving seat 3 facing the lifting seat 4, the lifting guide rail 81 and the lifting screw rod 83 extend in the vertical direction, the lifting motor 84 is used for driving the lifting screw rod 83 to rotate, the lifting slide block 82 is slidably arranged on the lifting guide rail 81, and the lifting nut 85 and the lifting screw rod 83 are sleeved outside the lifting screw rod 83 in a matched manner. The above-mentioned structure of the lifting screw 83 and the lifting nut 85 is a common screw driving structure for converting a rotary motion into a linear motion.

Referring to fig. 2, 4 and 5, the cross-beam 2 is provided with a cross-section having a substantially rectangular shape with oblique corners (i.e., a substantially rectangular-like square structure). The main body of the traversing seat 3 is sleeved outside the beam 2 in a square frame shape, the square frame-shaped structure of the main body of the traversing seat 3 is a square frame-shaped structure enclosed by four flat plates arranged around the beam 2, and the two side plates of the traversing seat 3 provided with the lifting seat 4 are arranged to protrude out of the main body of the traversing seat 3 in a vertically extending manner. The engraving device 62 includes an electric spindle for driving the engraving head to rotate and an engraving head. The saw blade processing device 61 includes a processing saw blade 611 and a processing motor 612, the processing saw blade 611 and the processing motor 612 are respectively assembled on the lifting seat 4 through a mounting arm 613, the processing motor 612 is disposed above the processing saw blade 611, and the processing motor 612 is used for driving the processing saw blade 611 to rotate. The end of the mounting arm 613 is fixedly mounted on the side of the lifting base 4, and the processing motor 612 and the processing blade 611 are mounted on the side of the mounting arm 613 located on the side in the lateral direction. The lifting base 4 provided with the saw blade processing device 61 is provided in a plate shape, two mounting arms 613 provided on the lifting base 4 are respectively provided at the upper and lower ends of the lifting base 4 and are respectively provided adjacent to the side edges of both sides in the width direction of the lifting base 4, and the processing motor 612 and the processing saw blade 611 are respectively assembled on the opposite sides of the two mounting arms 613.

Referring to fig. 2, 3, 4 and 5, the traverse base 3 is movably mounted in the transverse direction by a traverse mechanism. The traverse mechanism includes a traverse guide rail 91, a traverse rack 92, a traverse slider 93, and a traverse motor 94, the traverse guide rail 91 and the traverse rack 92 are both provided to extend in the transverse direction, and the traverse guide rail 91 and the traverse rack 92 are respectively provided to at least one of four outer surfaces of the cross beam 2 extending in the transverse direction. Each traverse seat 3 is attached with the traverse slider 93 and the traverse motor 94, the traverse slider 93 is disposed corresponding to the traverse guide rail 91 and is disposed on the inner side surface of the square frame-like structure of the traverse seat 3, and the traverse motor 94 is fixedly mounted on the traverse seat 3 where it is disposed. Each traverse motor 94 is attached with a traverse gear 941, and the traverse gear 941 is engaged with the traverse rack 92. Specifically, three traverse guide rails 91 are provided, and the three traverse guide rails 91 are respectively provided on the top surface of the cross member 2 and on both side surfaces of the cross member 2 in the longitudinal direction. The traverse rack 92 is provided on the top surface of the cross member 2. The lateral plates of the traverse table 3 on both sides of the lifting table 4 extend upward in the vertical direction, and the traverse motor 94 is provided between the extending ends of the lateral plates on both sides of the traverse table 3.

The above-mentioned be the utility model discloses a concrete implementation way, nevertheless the utility model discloses a design concept is not limited to this, and the ordinary use of this design is right the utility model discloses carry out immaterial change, all should belong to the act of infringement the protection scope of the utility model.

Claims (10)

1. A multi-head horizontal stone machining device comprises a rack, a cross beam, at least one transverse moving seat, a lifting seat, a workpiece table and a machining device, wherein the cross beam can be assembled on the rack in a longitudinally moving mode, the transverse moving seat can be assembled on the cross beam in a transversely moving mode, the transverse direction is the length direction of the cross beam, the lifting seat can be assembled on the transverse moving seat in a lifting mode relative to the transverse moving seat, the machining device is assembled on the lifting seat, the workpiece table is arranged below the cross beam and used for placing stone workpieces, and the machining device is used for machining the stone workpieces; the processing device is a saw blade processing device or an engraving processing device; the method is characterized in that: each transverse moving seat is correspondingly provided with two lifting seats, and the two lifting seats are respectively arranged on two sides of the corresponding transverse moving seat in the longitudinal direction; each lifting seat is provided with one processing device, and the processing devices are fixedly arranged on the side surface of one side of the lifting seat, which deviates from the transverse moving seat where the lifting seat is arranged.

2. The multi-head horizontal stone processing equipment as claimed in claim 1, wherein: each transverse moving seat is correspondingly provided with one workpiece table; the workpiece table is used for placing stone workpieces by jacking the end faces of two ends of the stone workpieces which are horizontally laid; the stone work pieces are arranged along the longitudinal extension after lying, and the extension direction of the stone work pieces is the extension direction of the stone work pieces from one supported surface to the other supported surface.

3. The multi-head horizontal stone processing equipment as claimed in claim 2, wherein: each workpiece table comprises a driving table seat, a driven table seat and a group of table seat slide rails, the table seat slide rails extend along the longitudinal direction, and the driving table seat and the driven table seat are respectively arranged on the table seat slide rails in a movable manner along the table seat slide rails; the driving pedestal is additionally provided with a driving propping part and a workpiece driving mechanism, the driving propping part is rotatably arranged on the driving pedestal, and the workpiece driving mechanism is assembled on the driving pedestal and is used for driving the driving propping part to rotate; the driven pedestal is additionally provided with a driven propping part and an adjusting handle wheel, the driven propping part is rotatably assembled on the driven pedestal, and the adjusting handle wheel is used for driving the driven propping part to move along the longitudinal direction; the driving propping part and the driven propping part are arranged oppositely.

4. The multi-head horizontal stone machining apparatus of claim 3, wherein: the driving pedestal is also additionally provided with a driving rotating shaft, and the driving rotating shaft is rotatably assembled at the top of the driving pedestal through at least two bearings; the driving jacking part is assembled at one end part of the driving rotating shaft, and the workpiece driving mechanism is in transmission connection with the other end part of the driving rotating shaft; the driven pedestal is also additionally provided with an adjusting seat and a driven rotating shaft, the adjusting seat can be assembled at the top of the driven pedestal along the longitudinal movement, the adjusting seat is driven by the adjusting handle to move, and the driven rotating shaft can be rotatably assembled at the top of the adjusting seat through at least two bearings; the driven supporting part is assembled at one end part of the driven rotating shaft facing the driving supporting part.

5. The multi-head horizontal stone processing equipment as claimed in claim 1, wherein: the machine frame comprises two side machine frames and a connecting machine frame, the two side machine frames are arranged in parallel along the longitudinal extension, and the connecting machine frame is connected with the bottoms of the two side machine frames; the workpiece table is arranged on the connecting rack; the end parts of the two ends of the cross beam are respectively assembled on the top surfaces of the two side frames.

6. The multi-head horizontal stone machining apparatus of claim 5, wherein: the side frame is additionally provided with a control box and an operation table, the control box is arranged in the side frame, and the operation table is assembled on the outer edge of the side frame; a box door is arranged on the side surface of the side frame, which is far away from the connecting frame, and the box door is communicated with the control box; the operation panel is assembled in side frame side edge by a swing arm, and the swing arm extends the setting along the horizontal direction, and the operation panel bottom can rotationally assemble in swing arm one end tip, and swing arm other end tip assembles in side frame side edge through a swing arm seat, and the swing arm can rotationally assemble the swing arm seat.

7. The multi-head horizontal stone machining apparatus of claim 5, wherein: the cross beam can be assembled in a longitudinally moving mode through a longitudinally moving mechanism; the longitudinal moving mechanism comprises longitudinal moving guide rails, longitudinal moving racks, longitudinal moving sliding blocks and longitudinal moving motors, the longitudinal moving guide rails and the longitudinal moving racks are arranged in a longitudinally extending mode and divided into two groups, the two groups of longitudinal moving guide rails and the longitudinal moving racks are respectively arranged at the tops of the two side racks, the longitudinal moving sliding blocks and the longitudinal moving motors are divided into two groups, the two groups of longitudinal moving sliding blocks and the longitudinal moving motors are respectively arranged at two ends of a cross beam, the longitudinal moving sliding blocks positioned on the same side are arranged on the longitudinal moving guide rails in a sliding mode, each longitudinal moving motor is additionally provided with a longitudinal moving gear, and the longitudinal moving gears positioned on the same side are connected with the longitudinal moving racks in a meshing mode; each lifting seat can be lifted and assembled relative to the transverse moving seat through a lifting mechanism; each elevating system all includes elevating guide, lifting slide, lift lead screw, elevator motor and lifting nut, and lifting slide and lifting nut fixed mounting are in the one side at the sideslip seat place of lift seat towards its place, and elevating guide, lift lead screw and elevator motor assemble in the sideslip seat towards one side of lift seat, and elevating guide and lift lead screw extend along vertical direction and set up, and elevator motor is used for driving the rotation of lift lead screw and sets up, and the sliding of lifting slide locates elevating guide, and the lifting nut overlaps with the lift lead screw is located outside the lift lead screw with supporting.

8. The multi-head horizontal stone processing equipment as claimed in claim 1, wherein: the cross section of the cross beam is arranged in a square shape; the main body part of the transverse moving seat is sleeved outside the beam in a square frame shape, and side plates at two sides of the transverse moving seat, which are provided with the lifting seat, are arranged to protrude out of the main body part of the transverse moving seat in a vertically extending manner; the two processing devices positioned on two sides of the same transverse moving seat are respectively a saw blade processing device and an engraving processing device which is an engraving processing device with an electric main shaft structure; the saw blade machining device comprises a machining saw blade and a machining motor, wherein the machining saw blade and the machining motor are respectively assembled on a lifting seat through a mounting arm, and the machining motor is arranged above the machining saw blade; the end part of the mounting arm is fixedly assembled on the side surface of the lifting seat, and the processing motor and the processing saw blade are respectively assembled on the side surface of the mounting arm on which the processing motor and the processing saw blade are respectively arranged and positioned in the transverse direction; the lifting seat provided with the saw blade machining device is in a plate-shaped arrangement, two mounting arms arranged on the lifting seat are respectively arranged at the upper end and the lower end of the lifting seat and are respectively adjacent to the side edges of the two sides of the lifting seat in the width direction, and the machining motor and the machining saw blade are respectively assembled on one side, opposite to the two mounting arms.

9. The multi-head horizontal stone processing equipment as claimed in claim 8, wherein: the transverse moving seat can be assembled in a transverse moving mode through a transverse moving mechanism; the transverse moving mechanism comprises a transverse moving guide rail, a transverse moving rack, a transverse moving slide block and a transverse moving motor, the transverse moving guide rail and the transverse moving rack are arranged in a transverse extending mode, and the transverse moving guide rail and the transverse moving rack are respectively arranged on at least one of four outer surfaces of the transverse beam extending in the transverse direction; each transverse moving seat is additionally provided with the transverse moving slide block and the transverse moving motor, the transverse moving slide block is arranged corresponding to the transverse moving guide rail and is arranged on the inner side surface of the square frame-shaped structure of the transverse moving seat, and the transverse moving motor is fixedly assembled on the transverse moving seat where the transverse moving slide block is arranged; each traverse motor is additionally provided with a traverse gear, and the traverse gear is meshed with the traverse rack.

10. The multi-head horizontal stone processing equipment as claimed in claim 9, wherein: three transverse guide rails are arranged and are respectively arranged on the top surface of the cross beam and the side surfaces of the cross beam at two sides in the longitudinal direction; the transverse rack is arranged on the top surface of the cross beam; the transverse moving seat is provided with two side plates of the lifting seat, the two side plates extend upwards along the vertical direction, and the transverse moving motor is arranged between the extending ends of the two side plates of the transverse moving seat.

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