CN218253477U - Large-breadth laser plate cutting machine - Google Patents

Abstract

The utility model relates to a panel cutting machine equipment technical field specifically is a big breadth laser panel cutting machine. Including cutting machine subassembly, firm subassembly, power component, state the inner wall of cutting machine lathe bed and seted up the lathe bed draw-in groove, firm subassembly includes firm bracing piece, the both ends symmetric connection of firm bracing piece has flexible chucking pole, the one end that flexible chucking pole was kept away from to the slip cardboard is connected with the chucking piece, power component includes the rotation handle. The utility model has the advantages that: when the slip cardboard slided, the synchronous motion of slip cardboard in gliding in-process drive chucking piece, then chucking piece inserts to the inside of lathe bed draw-in groove gradually at the in-process that removes to contact the laminating until the inner wall of chucking piece and lathe bed draw-in groove, and then realize cutting machine lathe bed and firm assembly's erection joint, the slip cardboard at this moment simultaneously all is located the inboard of lathe bed draw-in groove with chucking piece, thereby avoids firm assembly's slip.

Description

Large-breadth laser plate cutting machine

Technical Field

The utility model relates to a panel cutting machine equipment technical field specifically is a big breadth laser panel cutting machine.

Background

The laser cutting method is characterized in that a laser emitting light beam is adopted to punch holes on a product, a gap correspondingly generated according to horizontal movement is called laser cutting, the laser is excited by a substance to generate light, the light band has strong temperature, when the laser contacts with a material, the material can be rapidly melted on the surface of the material to form the punched holes, and cutting is formed according to the movement of the alignment points.

At present, use along with the needs of enterprise large format laser cutting machine more and more for extensively, nevertheless in the use, because large format laser cutting machine specification is comparatively huge, when the sword strip is installed in the cutting lathe bed, because self weight can produce slight flagging, this kind of phenomenon is when the cutting of the face of some heavier panels, and the operation that accompanies the crossbeam can make panel produce slight amplitude of oscillation, influences the product quality that the cutting came out.

The existing application numbers are: 202122694902.8 application document, a stabilizing device for a large-format laser cutting machine tool bar, which comprises a cutting machine body, wherein a plurality of tool bars are uniformly arranged between the inner walls of two sides of the cutting machine body, and the stabilizing device is arranged between the inner walls of two ends of the cutting machine body below the plurality of tool bars; this document suffers from the following disadvantages: first chucking piece, second chucking piece are direct and between the inner wall of cutting machine lathe bed both ends, and such fixed slip that causes first chucking piece, second chucking piece easily, and then can make the tightening rod can not prop tight sword strip, and then reduce the firm of securing device to the sword strip.

SUMMERY OF THE UTILITY MODEL

To above problem, the utility model aims to: the utility model provides a big breadth laser panel cutting machine, solve a chucking piece, the second chucking piece is between direct and cutting machine lathe bed both ends inner wall, such fixed first chucking piece that causes easily, the slip of second chucking piece, and then can make the tightening rod can not prop tight sword strip, and then reduce the firm of securing device to the sword strip, when sliding through when the slip cardboard, the synchronous motion of slip cardboard at gliding in-process drive chucking piece, then the chucking piece inserts the inside to the lathe bed draw-in groove gradually at the in-process that removes, and contact the laminating until the inner wall of chucking piece and lathe bed draw-in groove, and then realize cutting machine lathe bed and stabilizing component's erection joint, slip cardboard and chucking piece this moment all are located the inboard of lathe bed draw-in groove simultaneously, thereby avoid stabilizing component's gliding problem.

For the purpose of realizing above, the utility model discloses a technical scheme: the utility model provides a big breadth laser panel cutting machine, includes cutting machine subassembly, firm subassembly, power component, the cutting machine subassembly includes the cutting lathe bed, evenly be provided with a plurality of cutting tool strips between the inner wall of cutting machine lathe bed both sides, the lathe bed draw-in groove has been seted up to the inner wall of cutting machine lathe bed, firm subassembly includes firm bracing piece, the both ends symmetric connection of firm bracing piece has flexible chucking pole, slide clamping groove has been seted up to the inboard of flexible chucking pole, slide clamping groove's inboard is provided with the slip cardboard, the one end that flexible chucking pole was kept away from to the slip cardboard is connected with the chucking piece, power component includes the rotation handle, the one end of rotation handle is connected with first pivot, the outer lane of first pivot is connected with first bevel gear, the inboard of flexible chucking pole is provided with the second bevel gear, the inner wall connection of flexible chucking pole has the partition riser, the one end that the second bevel gear is close to the partition riser is connected with the threaded rod, the one end of separating the riser is connected with the gag lever, the one end that the partition riser is kept away from the gag lever is connected with the sliding block, the outer lane of gag lever is connected with the sliding block.

The utility model has the advantages that: after accomplishing the erection joint of firm subassembly and cutting machine lathe bed, the check baffle this moment is located between two adjacent cutting tool strips, and then can be used for propping tightly the cutting tool strip, when the slip cardboard slides, the synchronous motion of slip cardboard in gliding in-process drive chucking piece, then the chucking piece inserts the inside to the lathe bed draw-in groove gradually at the in-process that removes, and contact the laminating until the chucking piece and the inner wall of lathe bed draw-in groove, and then realize the erection joint of cutting machine lathe bed and firm subassembly, slip cardboard and chucking piece this moment all are located the inboard of lathe bed draw-in groove simultaneously, thereby avoid the slip of firm subassembly.

In order to realize the installation and connection of the cutting machine body and the stabilizing assembly:

as a further improvement of the above technical solution: the lower bottom surface of the cutting machine body is connected with a machine body base, the two machine body clamping grooves are formed, the two machine body clamping grooves are symmetrically arranged, and the size of each machine body clamping groove is matched with that of each clamping block.

The beneficial effect of this improvement does: the clamping block is arranged on the lathe bed base, and the clamping block is inserted into the channel through the clamping groove of the lathe bed, so that the installation and connection of the lathe bed and the stabilizing assembly of the cutting machine can be realized.

In order to be able to be used for bracing the cutting blade bar:

as a further improvement of the above technical solution: firm bracing piece and flexible chucking pole all are the rectangle structure setting, the top of firm bracing piece is connected with check baffle, the check baffle passes through the detachable installation in the top of firm bracing piece of connecting piece, adjacent two distance between the check baffle and the width phase-match of cutting tool strip.

The beneficial effect of this improvement does: after the installation and connection of the stabilizing assembly and the cutting machine body are completed, the grid baffle is positioned between two adjacent cutting tool bars, and then the grid baffle can be used for tightly supporting the cutting tool bars.

Channel for sliding the card:

as a further improvement of the technical scheme: the size of flexible chucking pole and the size phase-match of firm bracing piece, every flexible chucking pole has all seted up two the same sliding clamping groove of size, the inboard of flexible chucking pole is provided with chucking pole inside groove, sliding clamping groove and chucking pole inside groove communicate each other.

The beneficial effect of this improvement does: through the setting of slip draw-in groove for the slip cardboard carries out gliding passageway, through the setting of flexible chucking pole, is used for the protection to power component.

To avoid sliding of the stabilizing assembly:

as a further improvement of the technical scheme: the size of slide clamp plate and slide clamp groove's size phase-match, the quantity of chucking piece is the same with the quantity of flexible chucking pole.

The beneficial effect of this improvement does: when the slip cardboard slided, the synchronous motion of slip cardboard in gliding in-process drive chucking piece, then chucking piece inserts to the inside of lathe bed draw-in groove gradually at the in-process that removes to contact the laminating until the inner wall of chucking piece and lathe bed draw-in groove, and then realize cutting machine lathe bed and firm assembly's erection joint, the slip cardboard at this moment simultaneously all is located the inboard of lathe bed draw-in groove with chucking piece, thereby avoids firm assembly's slip.

In order to drive the first bevel gear to synchronously rotate in the rotating process of the first rotating shaft:

as a further improvement of the above technical solution: one end of the first rotating shaft, which is far away from the first bevel gear, penetrates through the wall body of the telescopic clamping rod and extends to be fixedly connected with the rotating handle, and the end of the first rotating shaft, which is far away from the rotating handle, is rotatably connected with the inner wall of the telescopic clamping rod through a connecting piece.

The beneficial effect of this improvement does: when the rotating handle is rotated, the rotating handle drives the first rotating shaft to synchronously rotate in the rotating process, and then the first rotating shaft drives the first bevel gear to synchronously rotate in the rotating process.

For use with a threaded rod and to effect linear movement of the sliding block:

as a further improvement of the technical scheme: the quantity of gag lever post is twice threaded rod quantity, gag lever post fixed connection is in separating the position between riser and the locating piece, gag lever post and sliding block swing joint.

The beneficial effect of this improvement does: through the setting of separating riser and locating piece for to the fixed of gag lever post, through the setting of gag lever post, be used for cooperating with the threaded rod and realize the linear motion of sliding block.

In order to realize the linear motion of the sliding clamping plate and the clamping block:

as a further improvement of the above technical solution: the threaded rod is in threaded rotary connection with the partition vertical plate and the sliding block, one end of the threaded rod, which is far away from the second bevel gear, is in rotary connection with the positioning block through a connecting piece, and the second bevel gear is in meshing transmission connection with the first bevel gear.

The beneficial effect of this improvement does: when the second bevel gear rotates under the action of the first bevel gear, the second bevel gear drives the threaded rod to synchronously rotate in the rotating process, and then the sliding block performs linear motion under the common acting force of the limiting rod and the threaded rod, so that the linear motion of the sliding clamping plate and the clamping block is realized.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic view of a three-dimensional structure of the cutting machine assembly of the present invention.

Fig. 3 is a schematic view of the three-dimensional structure of the stabilizing assembly of the present invention.

Fig. 4 is an enlarged schematic view of a portion a in fig. 3.

Fig. 5 is a schematic structural diagram of the power assembly of the present invention.

In the figure: 1. a cutter assembly; 11. cutting the lathe bed; 12. a bed base; 13. cutting the cutter bar; 14. a lathe bed clamping groove; 2. a stabilizing assembly; 21. the supporting rod is stabilized; 22. a telescopic clamping rod; 23. a sliding clamping groove; 24. a sliding clamping plate; 25. a clamping block; 26. a grid baffle; 27. clamping an inner groove of the rod; 3. a power assembly; 31. rotating the handle; 32. a first rotating shaft; 33. a first bevel gear; 34. a second bevel gear; 35. separating the vertical plate; 36. a limiting rod; 37. a threaded rod; 38. a slider; 39. and (5) positioning the blocks.

Detailed Description

In order to make the technical solutions of the present invention better understood by those skilled in the art, the present invention is described in detail below with reference to the accompanying drawings, and the description in this section is only exemplary and explanatory, and should not have any limiting effect on the scope of the present invention.

Example 1:

as shown in fig. 1-5, a large-format laser plate cutting machine includes a cutting machine assembly 1, a stabilizing assembly 2, and a power assembly 3, where the cutting machine assembly 1 includes a cutting machine bed 11, a plurality of cutting tool bars 13 are uniformly disposed between inner walls of two sides of the cutting machine bed 11, a bed clamping groove 14 is formed in the inner wall of the cutting machine bed 11, the stabilizing assembly 2 includes a stabilizing support rod 21, two ends of the stabilizing support rod 21 are symmetrically connected with telescopic clamping rods 22, a sliding clamping groove 23 is formed in the inner side of the telescopic clamping rod 22, a sliding clamping plate 24 is disposed on the inner side of the sliding clamping groove 23, one end of the sliding clamping plate 24, which is far away from the telescopic clamping rod 22, is connected with a clamping block 25, the power assembly 3 includes a rotating handle 31, one end of the rotating handle 31 is connected with a first rotating shaft 32, an outer ring of the first rotating shaft 32 is connected with a first bevel gear 33, an inner side of the telescopic clamping rod 22 is provided with a second bevel gear 34, an inner wall of the telescopic clamping rod 22 is connected with a partition 35, one end of the second bevel gear 34, which is close to the partition riser 35, one end of the riser is connected with a threaded rod 37, one end of the partition 36, one end of the riser 36 is connected with a stop lever 36, and an outer ring 36 of the stop block 36, and an outer ring 38 of the stop block 35 are connected with a slide block 38.

Example 2:

as shown in fig. 1 and 2, as a further optimization of the above embodiment, a large-format laser plate cutting machine includes a cutting machine assembly 1, a stabilizing assembly 2, and a power assembly 3, where the cutting machine assembly 1 includes a cutting machine bed 11, a plurality of cutting tool bars 13 are uniformly arranged between inner walls of two sides of the cutting machine bed 11, a bed clamping groove 14 is formed in the inner wall of the cutting machine bed 11, the stabilizing assembly 2 includes a stabilizing support rod 21, two ends of the stabilizing support rod 21 are symmetrically connected with telescopic clamping rods 22, a sliding clamping groove 23 is formed in the inner side of the telescopic clamping rod 22, a sliding clamping plate 24 is arranged in the inner side of the sliding clamping groove 23, one end of the sliding clamping plate 24, which is far away from the telescopic clamping rod 22, is connected with a clamping block 25, the power assembly 3 includes a rotating handle 31, one end of the rotating handle 31 is connected with a first rotating shaft 32, an outer ring of the first rotating shaft 32 is connected with a first bevel gear 33, an inner side of the telescopic clamping rod 22 is provided with a second bevel gear 34, an inner wall of the telescopic clamping rod 22 is connected with a separating vertical plate 35, one end of the second bevel gear 34 is connected with a limiting rod 36, and one end of the limiting rod 36 is connected with a limiting rod 36; the lower bottom surface of the cutting machine body 11 is connected with a body base 12, the two body clamping grooves 14 are formed in the body clamping grooves 14, the two body clamping grooves 14 are symmetrically arranged, and the size of each body clamping groove 14 is matched with that of the clamping block 25.

Example 3:

as shown in fig. 1, 2, and 3, as a further optimization of the above embodiment, a large-format laser plate cutting machine includes a cutting machine assembly 1, a stabilizing assembly 2, and a power assembly 3, where the cutting machine assembly 1 includes a cutting machine bed 11, a plurality of cutting tool bars 13 are uniformly arranged between inner walls of two sides of the cutting machine bed 11, a bed clamping groove 14 is formed in an inner wall of the cutting machine bed 11, the stabilizing assembly 2 includes a stabilizing support rod 21, two ends of the stabilizing support rod 21 are symmetrically connected with telescopic clamping rods 22, an inner side of the telescopic clamping rod 22 is provided with a sliding clamping groove 23, an inner side of the sliding clamping groove 23 is provided with a sliding clamping plate 24, one end of the sliding clamping plate 24, which is far away from the telescopic clamping rod 22, is connected with a clamping block 25, the power assembly 3 includes a rotating handle 31, one end of the rotating handle 31 is connected with a first rotating shaft 32, an outer ring of the first rotating shaft 32 is connected with a first bevel gear 33, an inner side of the telescopic clamping rod 22 is provided with a second bevel gear 34, an inner wall of the telescopic clamping rod 22 is connected with a separating vertical plate 35, one end of the second bevel gear 34, one end of the vertical plate 35 is connected with a positioning block 36, and one end of the vertical plate 35 is connected with a limiting rod 36; firm bracing piece 21 and flexible chucking pole 22 all are the setting of rectangle structure, the top of firm bracing piece 21 is connected with check baffle 26, check baffle 26 passes through the detachable installation in the top of firm bracing piece 21 of connecting piece, adjacent two distance between check baffle 26 and the width phase-match of cutting tool strip 13.

Example 4:

as shown in fig. 1, 2, and 4, as a further optimization of the above embodiment, a large-format laser plate cutting machine includes a cutting machine assembly 1, a stabilizing assembly 2, and a power assembly 3, where the cutting machine assembly 1 includes a cutting machine bed 11, a plurality of cutting tool bars 13 are uniformly arranged between inner walls of two sides of the cutting machine bed 11, a bed clamping groove 14 is formed in an inner wall of the cutting machine bed 11, the stabilizing assembly 2 includes a stabilizing support rod 21, two ends of the stabilizing support rod 21 are symmetrically connected with telescopic clamping rods 22, an inner side of the telescopic clamping rod 22 is provided with a sliding clamping groove 23, an inner side of the sliding clamping groove 23 is provided with a sliding clamping plate 24, one end of the sliding clamping plate 24, which is far away from the telescopic clamping rod 22, is connected with a clamping block 25, the power assembly 3 includes a rotating handle 31, one end of the rotating handle 31 is connected with a first rotating shaft 32, an outer ring of the first rotating shaft 32 is connected with a first bevel gear 33, an inner side of the telescopic clamping rod 22 is provided with a second bevel gear 34, an inner wall of the telescopic clamping rod 22 is connected with a separating vertical plate 35, one end of the second bevel gear 34, one end of the vertical plate 35 is connected with a positioning block 36, and one end of the vertical plate 35 is connected with a limiting rod 36; the size of the telescopic clamping rod 22 is matched with that of the stable supporting rod 21, two sliding clamping grooves 23 with the same size are formed in each telescopic clamping rod 22, a clamping rod inner groove 27 is formed in the inner side of each telescopic clamping rod 22, and the sliding clamping grooves 23 are communicated with the clamping rod inner grooves 27.

Example 5:

as shown in fig. 4 and 5, as a further optimization of the above embodiment, a large-format laser plate cutting machine includes a cutting machine assembly 1, a stabilizing assembly 2, and a power assembly 3, where the cutting machine assembly 1 includes a cutting machine bed 11, a plurality of cutting tool bars 13 are uniformly arranged between inner walls of two sides of the cutting machine bed 11, a bed clamping groove 14 is formed in the inner wall of the cutting machine bed 11, the stabilizing assembly 2 includes a stabilizing support rod 21, two ends of the stabilizing support rod 21 are symmetrically connected with telescopic clamping rods 22, a sliding clamping groove 23 is formed in the inner side of the telescopic clamping rod 22, a sliding clamping plate 24 is arranged in the inner side of the sliding clamping groove 23, one end of the sliding clamping plate 24, which is far away from the telescopic clamping rod 22, is connected with a clamping block 25, the power assembly 3 includes a rotating handle 31, one end of the rotating handle 31 is connected with a first rotating shaft 32, an outer ring of the first rotating shaft 32 is connected with a first bevel gear 33, an inner side of the telescopic clamping rod 22 is provided with a second bevel gear 34, an inner wall of the telescopic clamping rod 22 is connected with a separating vertical plate 35, one end of the second bevel gear 34 is connected with a limiting rod 36, and one end of the limiting rod 36 is connected with a limiting rod 36; the size of the sliding clamping plate 24 is matched with that of the sliding clamping groove 23, and the number of the clamping blocks 25 is the same as that of the telescopic clamping rods 22.

Example 6:

as shown in fig. 5, as a further optimization of the above embodiment, a large-format laser plate cutting machine includes a cutting machine assembly 1, a stabilizing assembly 2, and a power assembly 3, where the cutting machine assembly 1 includes a cutting machine bed 11, a plurality of cutting tool bars 13 are uniformly arranged between inner walls of two sides of the cutting machine bed 11, a bed clamping groove 14 is formed in the inner wall of the cutting machine bed 11, the stabilizing assembly 2 includes a stabilizing support rod 21, two ends of the stabilizing support rod 21 are symmetrically connected with telescopic clamping rods 22, the inner side of the telescopic clamping rod 22 is provided with a sliding clamping groove 23, the inner side of the sliding clamping groove 23 is provided with a sliding clamping plate 24, one end of the sliding clamping plate 24, which is far away from the telescopic clamping rod 22, is connected with a clamping block 25, the power assembly 3 includes a rotating handle 31, one end of the rotating handle 31 is connected with a first rotating shaft 32, the outer ring of the first rotating shaft 32 is connected with a first bevel gear 33, the inner side of the telescopic clamping rod 22 is provided with a second bevel gear 34, the inner wall of the telescopic clamping rod 24 is connected with a separating riser 35, one end of the second riser 34, one end of the riser 35 is connected with a separating riser 35, and one end of the limiting rod 36 is connected with a limiting block 36; one end of the first rotating shaft 32, which is far away from the first bevel gear 33, penetrates through the wall body of the telescopic clamping rod 22 and extends to be fixedly connected with the rotating handle 31, and one end of the first rotating shaft 32, which is far away from the rotating handle 31, is rotatably connected with the inner wall of the telescopic clamping rod 22 through a connecting piece.

Example 7:

as shown in fig. 5, as a further optimization of the above embodiment, a large-format laser plate cutting machine includes a cutting machine assembly 1, a stabilizing assembly 2, and a power assembly 3, where the cutting machine assembly 1 includes a cutting machine bed 11, a plurality of cutting tool bars 13 are uniformly arranged between inner walls of two sides of the cutting machine bed 11, a bed clamping groove 14 is formed in the inner wall of the cutting machine bed 11, the stabilizing assembly 2 includes a stabilizing support rod 21, two ends of the stabilizing support rod 21 are symmetrically connected with telescopic clamping rods 22, the inner side of the telescopic clamping rod 22 is provided with a sliding clamping groove 23, the inner side of the sliding clamping groove 23 is provided with a sliding clamping plate 24, one end of the sliding clamping plate 24, which is far away from the telescopic clamping rod 22, is connected with a clamping block 25, the power assembly 3 includes a rotating handle 31, one end of the rotating handle 31 is connected with a first rotating shaft 32, the outer ring of the first rotating shaft 32 is connected with a first bevel gear 33, the inner side of the telescopic clamping rod 22 is provided with a second bevel gear 34, the inner wall of the telescopic clamping rod 24 is connected with a separating riser 35, one end of the second riser 34, one end of the riser 35 is connected with a separating riser 35, and one end of the limiting rod 36 is connected with a limiting block 36; the number of the limiting rods 36 is twice that of the threaded rods 37, the limiting rods 36 are fixedly connected between the partition vertical plate 35 and the positioning block 39, and the limiting rods 36 are movably connected with the sliding blocks 38.

Example 8:

as shown in fig. 5, as a further optimization of the above embodiment, a large-format laser plate cutting machine includes a cutting machine assembly 1, a stabilizing assembly 2, and a power assembly 3, where the cutting machine assembly 1 includes a cutting machine bed 11, a plurality of cutting tool bars 13 are uniformly arranged between inner walls of two sides of the cutting machine bed 11, a bed clamping groove 14 is formed in the inner wall of the cutting machine bed 11, the stabilizing assembly 2 includes a stabilizing support rod 21, two ends of the stabilizing support rod 21 are symmetrically connected with telescopic clamping rods 22, the inner side of the telescopic clamping rod 22 is provided with a sliding clamping groove 23, the inner side of the sliding clamping groove 23 is provided with a sliding clamping plate 24, one end of the sliding clamping plate 24, which is far away from the telescopic clamping rod 22, is connected with a clamping block 25, the power assembly 3 includes a rotating handle 31, one end of the rotating handle 31 is connected with a first rotating shaft 32, the outer ring of the first rotating shaft 32 is connected with a first bevel gear 33, the inner side of the telescopic clamping rod 22 is provided with a second bevel gear 34, the inner wall of the telescopic clamping rod 24 is connected with a separating riser 35, one end of the second riser 34, one end of the riser 35 is connected with a separating riser 35, and one end of the limiting rod 36 is connected with a limiting block 36; the threaded rod 37 is in threaded rotary connection with both the partition vertical plate 35 and the sliding block 38, one end of the threaded rod 37, which is far away from the second bevel gear 34, is in rotary connection with the positioning block 39 through a connecting piece, and the second bevel gear 34 is in meshing transmission connection with the first bevel gear 33.

The utility model discloses a theory of operation does: when the cutting machine is used, the stabilizing component 2 is stably placed on the inner side of the machine tool body 11, then the rotating handle 31 is rotated, the rotating handle 31 drives the first rotating shaft 32 to synchronously rotate in the rotating process, then the first rotating shaft 32 drives the first bevel gear 33 to synchronously rotate in the rotating process, when the second bevel gear 34 rotates under the action of the first bevel gear 33, the second bevel gear 34 drives the threaded rod 37 to synchronously rotate in the rotating process, then the sliding block 38 linearly moves under the common acting force of the limiting rod 36 and the threaded rod 37, so that the sliding clamping block 24 and the clamping block 25 are linearly moved, the clamping block 25 is gradually inserted into the clamping groove 14 in the moving process through the arrangement of the limiting rod 36 to realize the linear movement of the sliding block 38, when the sliding clamping block 24 slides, the sliding block 24 drives the clamping block 25 to synchronously move in the sliding process, then the clamping block 25 is gradually inserted into the clamping groove 14 until the clamping block 25 and the clamping block 25 are matched with the threaded rod 37, so that the inner wall of the clamping block 24 and the clamping block 24 are stably connected with the clamping component 2 of the cutting machine tool body 11, at the clamping block 24, and the clamping block 24 are stably connected with the cutting machine tool body, at the clamping block 12, and the clamping block 24, so that the clamping block 24 is stably connected with the cutting machine tool body 12, and the cutting machine tool body 11, and the cutting machine tool is connected with the cutting machine tool body 12, and the clamping block 24, the clamping block is used for fixing and supporting the cutting machine body 11, and is used for a channel for inserting the clamping block 25 through the arrangement of the machine body clamping groove 14, so that the installation and connection of the cutting machine body 11 and the stabilizing component 2 can be realized.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The principles and embodiments of the present invention have been explained herein using specific examples, which are presented only to assist in understanding the methods and their core concepts. The foregoing is only a preferred embodiment of the present invention, and it should be noted that there are practically unlimited specific structures due to the limited character expressions, and it will be apparent to those skilled in the art that a plurality of modifications, decorations or changes can be made without departing from the principle of the present invention, and the technical features described above can also be combined in a suitable manner; the present invention is intended to cover such modifications, variations, or combinations, which may be used to advantage or without modification to practice of the invention.

Claims (8)

1. The utility model provides a big breadth laser panel cutting machine, includes cutting machine subassembly (1), firm subassembly (2), power component (3), its characterized in that: the cutting machine assembly (1) comprises a cutting machine body (11), a plurality of cutting tool bars (13) are uniformly arranged between the inner walls of the two sides of the cutting machine body (11), a machine body clamping groove (14) is formed in the inner wall of the cutting machine body (11), the stabilizing assembly (2) comprises a stabilizing support rod (21), telescopic clamping rods (22) are symmetrically connected to the two ends of the stabilizing support rod (21), a sliding clamping groove (23) is formed in the inner side of each telescopic clamping rod (22), a sliding clamping plate (24) is arranged on the inner side of each sliding clamping groove (23), one end, far away from each telescopic clamping rod (22), of each sliding clamping plate (24) is connected with a clamping block (25), the power assembly (3) comprises a rotating handle (31), one end of the rotating handle (31) is connected with a first rotating shaft (32), the outer ring of the first rotating shaft (32) is connected with a first bevel gear (33), the inner side of each telescopic clamping rod (22) is provided with a second bevel gear (34), the inner wall of each telescopic clamping rod (22) is connected with a partition vertical plate (35), one end, close to one end of each partition vertical plate (35), one end of each second bevel gear (34) is connected with a limiting rod (36), and one end, far away from each limiting rod (35) is connected with a limiting rod (36), the outer ring of the limiting rod (36) is connected with a sliding block (38).

2. The large format laser cutting machine of claim 1, wherein: the lower bottom surface of the cutting machine body (11) is connected with a body base (12), the number of the body clamping grooves (14) is two, the body clamping grooves (14) are symmetrically arranged, and the size of the body clamping grooves (14) is matched with that of the clamping block (25).

3. The large format laser cutting machine of claim 1, wherein: firm bracing piece (21) and flexible chucking pole (22) all are the rectangle structure setting, the top of firm bracing piece (21) is connected with check baffle (26), check baffle (26) are through the detachable installation in the top of firm bracing piece (21) of connecting piece, adjacent two distance between check baffle (26) and the width phase-match of cutting tool strip (13).

4. The large format laser cutting machine of claim 1, wherein: the size of flexible chucking pole (22) and the size phase-match of firm bracing piece (21), every flexible chucking pole (22) have all been seted up two slide clamping groove (23) that the size is the same, the inboard of flexible chucking pole (22) is provided with chucking pole inside groove (27), slide clamping groove (23) and chucking pole inside groove (27) communicate each other.

5. The large format laser cutting machine of claim 1, wherein: the size of the sliding clamping plate (24) is matched with that of the sliding clamping groove (23), and the number of the clamping blocks (25) is the same as that of the telescopic clamping rods (22).

6. The large format laser cutting machine of claim 1, wherein: one end, far away from the first bevel gear (33), of the first rotating shaft (32) penetrates through the wall body of the telescopic clamping rod (22) and extends to be fixedly connected with the rotating handle (31), and one end, far away from the rotating handle (31), of the first rotating shaft (32) is rotatably connected with the inner wall of the telescopic clamping rod (22) through a connecting piece.

7. The large format laser cutting machine of claim 1, wherein: the number of the limiting rods (36) is twice that of the threaded rods (37), the limiting rods (36) are fixedly connected to positions between the partition vertical plates (35) and the positioning blocks (39), and the limiting rods (36) are movably connected with the sliding blocks (38).

8. The large format laser cutting machine of claim 1, wherein: the threaded rod (37) is in threaded rotary connection with both the partition vertical plate (35) and the sliding block (38), one end of the threaded rod (37) far away from the second bevel gear (34) is in threaded rotary connection with the positioning block (39) through a connecting piece, and the second bevel gear (34) is in meshed transmission connection with the first bevel gear (33).

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