CN113070568A - Mirror surface stainless steel sheet metal full-automatic unloading laser high efficiency cutting system of going up - Google Patents

Abstract

The invention discloses a full-automatic loading and unloading laser high-efficiency cutting system for a mirror surface stainless steel sheet, which belongs to the technical field of laser cutting devices and comprises a support frame, wherein supporting legs are uniformly arranged at the bottom of the support frame, a rotary disc is arranged at the top of the support frame, the top of the rotary disc is rotatably connected with a first connecting block, the top of the first connecting block is rotatably connected with a rotary plate, the outer side wall of the rotary plate is fixedly connected with a push plate, a first rotary rod is fixed at the bottom of the rotary disc, and the bottom of the first rotary rod penetrates through the inner cavity of the support frame and is connected with a first bevel gear; the invention can fully automatically feed and discharge the mirror surface stainless steel sheet, thereby saving a large amount of labor force and reducing the manufacturing cost.

Description

Mirror surface stainless steel sheet metal full-automatic unloading laser high efficiency cutting system of going up

Technical Field

The invention relates to the technical field of laser cutting devices, in particular to a full-automatic loading and unloading laser efficient cutting system for a mirror surface stainless steel sheet.

Background

The process of processing and manufacturing the stainless steel mirror panel can be divided into two modes of normal grinding and fine grinding, so the mirror surface effect manufactured by the two processing modes is better, the judgment is needed by looking at the brightness of the surface of the mirror surface, and the sand holes and grinding head patterns on the surface of the plate are required to be less. Generally, stainless steel plates are processed on a polishing machine, and the slower the stainless steel plates travel, the more the groups are ground, and the better the effect is; when the stainless steel plate is processed by using polishing equipment, firstly, the plate is sanded, then the stainless steel plate is put into grinding liquid, wherein the stainless steel plate is ground by 8 groups of grinding heads with different thicknesses, the grinding processing is basically the surface treatment of the stainless steel plate, the process has no depth, the step is mainly used for removing the oxide layer on the surface of the stainless steel plate, the stainless steel plate is washed and dried after the above procedures are completed, and the color stainless steel mirror panel is colored on the basis of the stainless steel mirror panel.

The existing mirror surface stainless steel sheet edge cutting machine is expensive in manufacturing cost, a large amount of personnel are needed to operate the existing mirror surface stainless steel sheet processing machine, the operation and maintenance cost is very high, and the comprehensive economic benefit is not high.

Disclosure of Invention

The invention aims to solve the problems that in the prior art, a mirror surface stainless steel sheet processing machine needs a large amount of personnel to operate, the operation and maintenance cost is high, and the comprehensive economic benefit is not high, and provides a full-automatic loading and unloading laser high-efficiency cutting system for a mirror surface stainless steel sheet.

In order to achieve the purpose, the invention adopts the following technical scheme:

the full-automatic loading and unloading laser high-efficiency cutting system for the mirror surface stainless steel sheet comprises a support frame, wherein supporting legs are uniformly arranged at the bottom of the support frame, a rotary disc is arranged at the top of the support frame, the top of the rotary disc is rotatably connected with a first connecting block, the top of the first connecting block is rotatably connected with a rotary plate, the outer side wall of the rotary plate is fixedly connected with a push plate, a first rotary rod is fixed at the bottom of the rotary disc, the bottom of the first rotary rod, penetrating through the inner cavity of the support frame, is connected with a first bevel gear, the top of the support frame is fixedly connected with a storage box, the bottom of the storage box is provided with a through groove, the through groove and the push plate are positioned on the same horizontal line, the bottom of the support frame is fixedly connected with a storage box, the inner cavity of the storage box is fixedly, the left side and the right side of the containing box are respectively provided with a fifth rotating rod and a sixth rotating rod, the sixth rotating rod and the fifth rotating rod are slidably connected with a sliding sleeve in a side view, an inner cavity of the sliding sleeve is drilled with a sliding groove, the sixth rotating rod and the fifth rotating rod are respectively positioned in the sliding groove, one sides of the two groups of sliding sleeves, which are far away from the sixth rotating rod and the fifth rotating rod, are respectively provided with a sixth conical gear, the sixth conical gear is meshed with a fourth conical gear, one end of the sixth rotating rod, which is far away from the motor, is connected with a seventh conical gear, the seventh conical gear is meshed with the first conical gear, the right end of the fifth rotating rod is fixedly connected with a fifth conical gear, the left side and the right side of the supporting frame are respectively provided with a first fixing frame and a second fixing frame, the inner cavity of the first fixing frame is provided with a third rotating rod, and the top of the third rotating rod is, the bottom of third bull stick runs through the inner chamber bottom of first mount and installs third bevel gear, third bevel gear meshes with fifth bevel gear mutually, the side of looking mutually of first mount and second mount is provided with fourth bull stick and wire guide pole respectively, the left side of fourth bull stick runs through first mount and is connected with conical bevel gear, second conical gear meshes with conical bevel gear mutually, the laser cutting head is installed with the lateral wall of wire guide pole to the fourth bull stick.

Preferably, the outer side wall of the fifth rotating rod is fixedly connected with a convex block, a sliding groove is formed in the inner cavity of the sliding sleeve in a chiseled mode, and the convex block is located inside the sliding groove.

Preferably, the lateral wall fixedly connected with connecting rod of sliding sleeve, the lateral wall of containing box is dug there is the through-hole, one side that the sliding sleeve was kept away from to the connecting rod is located the through-hole, the lateral wall fixedly connected with cylinder of containing box, the lateral wall at the connecting rod is connected to the output of cylinder.

Preferably, the right side wall of support frame rotates even has the slide, the right side fixedly connected with stopper of support frame, the stopper is located the bottom of support frame, the top of slide and conveyer belt is located same horizontal plane.

Preferably, the top of the rotating plate is provided with an arc-shaped groove in a chiseled mode, the top and the bottom of the first connecting block are fixedly connected with a connecting column, the bottom of the connecting column is fixedly connected to the top of the rotating plate, and the top of the connecting column is located inside the arc-shaped groove.

Preferably, the left and right sides of conveyer belt all rotates and is connected with the second bull stick, and the left side the second bull stick front side runs through the support frame and is connected with the runner.

Preferably, the outer wall of commentaries on classics board and push pedal is connected with the bracing piece, the top fixedly connected with fixed block of support frame, bracing piece sliding connection is inboard at the fixed block.

Preferably, the equal fixedly connected with stopper in the bottom left and right sides of support frame, fifth bull stick and sixth bull stick are all rotated and are connected in the stopper.

Compared with the prior art, the invention provides a full-automatic loading and unloading laser high-efficiency cutting system for a mirror surface stainless steel sheet, which has the following beneficial effects:

1. according to the full-automatic loading and unloading laser high-efficiency cutting system for the mirror surface stainless steel sheets, the push plate pushes the mirror surface stainless steel sheets in the through grooves to move towards the right side in the process of moving towards the right side, so that the mirror surface stainless steel sheets slide onto the conveying belt, when the push plate moves towards the left side, the mirror surface stainless steel sheets placed in the storage box slide downwards into the through grooves, then the mirror surface stainless steel sheets are pushed out through the push plate again, the mirror surface stainless steel sheets in the storage box are pushed out in a reciprocating mode, after the mirror surface stainless steel sheets are cut through the conveying belt, the mirror surface stainless steel sheets are conveyed onto the sliding plate through the conveying belt to be unloaded, and therefore the full-automatic loading and unloading of the mirror surface stainless steel sheets;

2. according to the full-automatic loading and unloading laser high-efficiency cutting system for the mirror surface stainless steel sheet, the sliding sleeves arranged on the fifth rotating rod and the sixth rotating rod can move left and right through the arrangement of the convex blocks and the sliding grooves, the output end of the air cylinder can drive the sliding sleeves to move left and right through the arrangement of the connecting rods and the through holes, and the fifth rotating rod and the sixth rotating rod can rotate or stop rotating;

3. according to the full-automatic feeding and discharging laser high-efficiency cutting system for the mirror surface stainless steel sheet, the sliding plate is prevented from inclining ninety degrees downwards through the arrangement of the limiting block, the mirror surface stainless steel sheet directly slides to the ground, so that the mirror surface stainless steel sheet is damaged, the rotating plate cannot move left and right when the connecting column arranged by the first connecting block is arranged in the arc-shaped groove to change the position through the arrangement of the arc-shaped groove, and the rotating plate cannot be broken due to overlarge front and back stress;

4. this full-automatic unloading laser high efficiency cutting system of going up of mirror surface stainless steel sheet metal can drive the runner through actuating mechanism through the setting of runner and rotate to cooperation laser cutting head removes, and the motor can drive the laser cutting head back-and-forth movement at clockwise or anticlockwise rotatory in-process, makes the condition of droing can not appear at rotatory in-process in fifth bull stick and sixth bull stick through setting up of stopper.

Drawings

FIG. 1 is a schematic structural diagram of a full-automatic loading and unloading laser high-efficiency cutting system for a mirror surface stainless steel sheet according to the present invention;

FIG. 2 is a cross-sectional view of a full-automatic laser high-efficiency cutting system for loading and unloading mirror surface stainless steel sheets, which is provided by the invention;

FIG. 3 is a top view of a full-automatic loading and unloading laser high-efficiency cutting system for mirror surface stainless steel sheets according to the present invention;

FIG. 4 is a connection intention of a chute and a guide rod of the full-automatic loading and unloading laser high-efficiency cutting system for the mirror surface stainless steel sheet provided by the invention;

FIG. 5 is an enlarged view of section A of the full-automatic laser high-efficiency cutting system for feeding and discharging mirror-finished stainless steel sheets provided by the invention;

FIG. 6 is a cross-sectional view of a first fixing frame of a full-automatic loading and unloading laser high-efficiency cutting system for a mirror surface stainless steel sheet according to the present invention;

FIG. 7 is a schematic structural view of a storage box of the full-automatic loading and unloading laser high-efficiency cutting system for mirror surface stainless steel sheets according to the present invention;

FIG. 8 is a cross-sectional view of a sliding sleeve of a full-automatic loading and unloading laser high-efficiency cutting system for a mirror surface stainless steel sheet according to the present invention;

FIG. 9 is a schematic structural diagram of a bump of a full-automatic loading and unloading laser high-efficiency cutting system for a mirror surface stainless steel sheet according to the present invention;

fig. 10 is a schematic structural diagram of a push plate of a mirror-surface stainless steel sheet full-automatic loading and unloading laser high-efficiency cutting system provided by the invention.

In the figure: 100. a support frame; 110. a support leg; 120. a turntable; 121. a first connection block; 122. rotating the plate; 123. a first rotating lever; 124. a first bevel gear; 130. pushing the plate; 140. a storage tank; 141. a through groove; 150. a conveyor belt; 151. a second rotating rod; 160. a first fixing frame; 161. a third rotating rod; 162. a second bevel gear; 163. a third bevel gear; 164. a laser cutting head; 165. a fourth rotating rod; 166. a wire guide rod; 167. a second fixing frame; 170. a slide plate; 200. a storage box; 201. a cylinder; 210. a motor; 211. a connecting rod; 220. a fourth bevel gear; 230. a fifth rotating rod; 231. a fifth bevel gear; 240. a sliding sleeve; 241. a chute; 242. a fifth bevel gear; 250. a sixth rotating rod; 251. a seventh bevel gear.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Example 1:

referring to fig. 1-10, a full-automatic loading and unloading laser high-efficiency cutting system for mirror surface stainless steel sheets comprises a support frame 100, supporting legs 110 are uniformly and fixedly arranged at the bottom of the support frame 100, a rotary table 120 is arranged at the top of the support frame 100, a first connecting block 121 is rotatably connected at the top of the rotary table 120, a rotary plate 122 is rotatably connected at the top of the first connecting block 121, a push plate 130 is fixedly connected at the outer side wall of the rotary plate 122, a first rotary rod 123 is fixed at the bottom of the rotary table 120, a first bevel gear 124 is connected at the bottom of the first rotary rod 123 through an inner cavity of the support frame 100, a storage box 140 is fixedly connected at the top of the support frame 100, a through groove 141 is formed at the bottom of the storage box 140, a conveying belt 150 is arranged at the top of the support frame 100, the through groove 141 and the push plate, the output end of the motor 210 is fixedly connected with a fourth bevel gear 220, the left and right sides of the storage box 200 are respectively provided with a fifth rotating rod 230 and a sixth rotating rod 250, the sixth rotating rod 250 and the fifth rotating rod 230 are connected with a sliding sleeve 240 in a sliding manner, the inner cavity of the sliding sleeve 240 is provided with a sliding groove 241, the sixth rotating rod 250 and the fifth rotating rod 230 are respectively positioned in the sliding groove 241, one sides of the two groups of sliding sleeves 240 far away from the sixth rotating rod 250 and the fifth rotating rod 230 are respectively provided with a sixth bevel gear 242, the sixth bevel gear 242 is meshed with the fourth bevel gear 220, one end of the sixth rotating rod 250 far away from the motor 210 is connected with a seventh bevel gear 251, the seventh bevel gear 251 is meshed with a first bevel gear 124, the right end of the fifth rotating rod 230 is fixedly connected with a fifth bevel gear 231, the left and right sides of the support frame 100 are respectively provided with a first fixing frame 160 and a second fixing frame 167, the inner cavity of the first fixing frame 160 is provided, the top of the third rotating rod 161 is fixedly connected with a second bevel gear 162, the bottom of the third rotating rod 161 penetrates through the bottom of the inner cavity of the first fixing frame 160 and is provided with a third bevel gear 163, the third bevel gear 163 is meshed with a fifth bevel gear 231, the viewing sides of the first fixing frame 160 and the second fixing frame 167 are respectively provided with a fourth rotating rod 165 and a wire guide rod 166, the left side of the fourth rotating rod 165 penetrates through the first fixing frame 160 and is connected with the tapered bevel gear, the second bevel gear 162 is meshed with the tapered bevel gear, and the outer side walls of the fourth rotating rod 165 and the wire guide rod 166 are provided with a laser cutting head 164.

When the device is used, firstly, a mirror surface stainless steel sheet is placed in the storage box 140, by starting the motor 210, the motor 210 drives the fourth bevel gear 220 to rotate in the rotating process, the fourth bevel gear 220 drives the sixth bevel gear 242 to rotate in the rotating process, the sixth bevel gear 242 drives the sliding sleeve 240 to rotate in the rotating process, the sliding sleeve 240 respectively drives the fifth rotating rod 230 and the sixth rotating rod 250 to rotate in the rotating process, the connecting rod 211 is respectively driven to move left and right by the output end of the cylinder 201 through the cylinder 201 which is a bidirectional cylinder, the sixth rotating rod 250 is driven to rotate in the process that the connecting rod 211 moves right, the sixth rotating rod 250 drives the seventh bevel gear 251 to rotate in the rotating process, the seventh bevel gear 251 drives the third bevel gear 163 to rotate in the rotating process, the third bevel gear 163 drives the third rotating rod 161 to rotate in the rotating process, the third rotating rod 161 drives the second bevel gear 162 to rotate in the rotating process, the second bevel gear 162 drives the bevel gear arranged on the fourth rotating rod 165 to rotate in the rotating process, the fourth rotating rod 165 drives the laser cutting head 164 to move left and right through the design of the wire guiding rod 166 in the rotating process, the laser cutting head 164 cuts the mirror surface stainless steel sheet in the left and right moving process, when the left output end of the air cylinder 201 pushes the left sliding sleeve 240 to move right, the sixth bevel gear 242 is meshed with the fourth bevel gear 220 to drive the fifth rotating rod 230 to rotate, the fifth rotating rod 230 drives the fifth bevel gear 231 to rotate in the rotating process, the fifth bevel gear 231 drives the first bevel gear 124 to rotate in the rotating process, the first bevel gear 124 drives the first rotating rod 123 to rotate in the rotating process, the first rotating rod 123 drives the rotating disc 120 to rotate in the rotating process, the rotating disc 120 drives the first connecting block 121 to rotate in the rotating process, the first connecting block 121 drives the rotating plate 122 to move left and right, the rotating plate 122 pushes the push plate 130 to move left and right in the left and right processes, the push plate 130 pushes the mirror surface stainless steel sheet in the through groove 141 to move right in the process of moving right, so that the mirror surface stainless steel sheet slides onto the conveying belt 150, when the push plate 130 moves left, the mirror surface stainless steel sheet is placed in the storage box 140 to slide down and fall into the through groove 141, then the mirror surface stainless steel sheet is pushed out again through the push plate 130, the mirror surface stainless steel sheet in the storage box 140 is pushed out in a reciprocating manner, after the mirror surface stainless steel sheet is cut by the conveying belt 150, the mirror surface stainless steel sheet is conveyed to the sliding plate 170 through the conveying belt 150 to be fed, thereby realize full-automatic material loading and unloading to the mirror surface stainless steel sheet metal.

Example 2:

referring to fig. 5 and 9, a mirror surface stainless steel sheet full-automatic loading and unloading laser high-efficiency cutting system is substantially the same as that in embodiment 1, further, a convex block is fixedly connected to an outer side wall of the fifth rotating rod 230, a sliding groove is formed in an inner cavity of the sliding sleeve 240, the convex block is located inside the sliding groove, a connecting rod 211 is fixedly connected to an outer side wall of the sliding sleeve 240, a through hole is formed in an outer side wall of the storage box 200, one side of the connecting rod 211, which is far away from the sliding sleeve 240, is located in the through hole, an air cylinder 201 is fixedly connected to an outer side wall of the storage box 200, and an output;

the sliding sleeve 240 arranged on the fifth rotating rod 230 and the sixth rotating rod 250 can move left and right through the arrangement of the convex block and the sliding groove, and the output end of the air cylinder 201 can drive the sliding sleeve 240 to move left and right through the arrangement of the connecting rod 211 and the through hole, so that the fifth rotating rod 230 and the sixth rotating rod 250 rotate or stop rotating.

Example 3:

referring to fig. 3, a full-automatic unloading laser high efficiency cutting system that goes up of mirror surface stainless steel sheet metal, the same with embodiment 1, further, the right side wall of support frame 100 rotates even has slide 170, the right side fixedly connected with stopper of support frame 100, the stopper is located slide 170's bottom, slide 170 is located same horizontal plane with conveyer belt 150's top, the top of commentaries on classics board 122 is opened and is dug the arc wall, the top and the equal fixedly connected with spliced pole in bottom of first splice 121, the bottom fixed connection of bottom spliced pole is at the top of carousel 120, the top of top spliced pole is located inside the arc wall.

Set up through the stopper and prevent that slide 170 from ninety degrees slopes down, slide 170 is located same horizontal plane with the top of conveyer belt 150, when conveyer belt 150 carried the stainless steel sheet metal slide 170 on, make the direct landing of mirror surface stainless steel sheet metal to ground, thereby lead to the damage of mirror surface stainless steel sheet metal, the spliced pole that can first connecting block 121 set up through setting up of arc wall can not make when changing the position in the arc wall change and move about commentaries on classics board 122, thereby the atress is too big around can not appearing and leads to changeing board 122 fracture.

Example 4:

referring to fig. 1 and fig. 3, a full-automatic unloading laser high efficiency cutting system of going up of mirror surface stainless steel sheet metal, basically the same with embodiment 1, further, the left and right sides of conveyer belt 150 all rotates and is connected with second bull stick 151, left side second bull stick 151 front side runs through support frame 100 and is connected with the runner, the outer wall connection of bull stick 122 and push pedal 130 has the bracing piece, the top fixedly connected with fixed block of support frame 100, bracing piece sliding connection is inboard at the fixed block, the equal fixedly connected with stopper in the bottom left and right sides of support frame 100, fifth bull stick 230 and sixth bull stick 250 all rotate and connect in the stopper.

The rotating wheel can be driven to rotate through the driving mechanism through the rotating wheel, so that the laser cutting head 164 is matched to move, the motor 210 can drive the laser cutting head 164 to move back and forth in the clockwise or anticlockwise rotating process, and the fifth rotating rod 230 and the sixth rotating rod 250 cannot fall off in the rotating process through the arrangement of the limiting block.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims (8)

1. The utility model provides a full-automatic unloading laser high efficiency cutting system that goes up of mirror surface stainless steel sheet metal, includes support frame (100), its characterized in that: the bottom of support frame (100) evenly is provided with landing leg (110), the top of support frame (100) is provided with carousel (120), the top of carousel (120) is rotated and is connected with first connecting block (121), the top of first connecting block (121) is rotated and is connected with commentaries on classics board (122), the lateral wall fixedly connected with push pedal (130) of commentaries on classics board (122), the bottom of carousel (120) is fixed with first bull stick (123), the inner chamber that the bottom of first bull stick (123) runs through support frame (100) is connected with first conical gear (124), the top fixedly connected with storage box (140) of support frame (100), open the chisel in the bottom of storage box (140) has logical groove (141), support frame (100) top is provided with conveyer belt (150), logical groove (141) are located same water flat line with push pedal (130), the bottom fixedly connected with containing box (200) of support frame (100), the inner cavity of the containing box (200) is fixedly provided with a motor (210), the output end of the motor (210) is fixedly connected with a fourth bevel gear (220), the left side and the right side of the containing box (200) are respectively provided with a fifth rotating rod (230) and a sixth rotating rod (250), the sixth rotating rod (250) and the fifth rotating rod (230) are in sliding connection with a sliding sleeve (240) in a side view, a sliding groove (241) is formed in the inner cavity of the sliding sleeve (240), the sixth rotating rod (250) and the fifth rotating rod (230) are respectively positioned in the sliding groove (241), one sides of the sliding sleeve (240) far away from the sixth rotating rod (250) and the fifth rotating rod (230) are respectively provided with a sixth bevel gear (242), the sixth bevel gear (242) is meshed with the fourth bevel gear (220), one end of the sixth rotating rod (250) far away from the motor (210) is connected with a seventh bevel gear (251), the seventh bevel gear (251) is meshed with the first bevel gear (124), a fifth bevel gear (231) is fixedly connected to the right end of the fifth rotating rod (230), a first fixing frame (160) and a second fixing frame (167) are respectively installed on the left side and the right side of the support frame (100), a third rotating rod (161) is arranged in an inner cavity of the first fixing frame (160), a second bevel gear (162) is fixedly connected to the top of the third rotating rod (161), a third bevel gear (163) is installed on the bottom of the inner cavity of the third rotating rod (161) penetrating through the first fixing frame (160), the third bevel gear (163) is meshed with the fifth bevel gear (231), a fourth rotating rod (165) and a lead rod (166) are respectively arranged on the viewing sides of the first fixing frame (160) and the second fixing frame (167), and the first fixing frame (160) is connected to the left side of the fourth rotating rod (165), the second conical gear (162) is meshed with the conical gear, and the laser cutting head (164) is installed on the outer side walls of the fourth rotating rod (165) and the wire guide rod (166).

2. The fully automatic loading and unloading laser high-efficiency cutting system for mirror-surface stainless steel sheets as claimed in claim 1, wherein a protrusion is fixedly connected to an outer side wall of the fifth rotating rod (230), a sliding groove is formed in an inner cavity of the sliding sleeve (240), and the protrusion is located inside the sliding groove.

3. The full-automatic feeding and discharging laser high-efficiency cutting system for the mirror-surface stainless steel sheets as claimed in claim 1, wherein a connecting rod (211) is fixedly connected to an outer side wall of the sliding sleeve (240), a through hole is formed in an outer side wall of the storage box (200), one side, away from the sliding sleeve (240), of the connecting rod (211) is located in the through hole, an air cylinder (201) is fixedly connected to an outer side wall of the storage box (200), and an output end of the air cylinder (201) is connected to an outer side wall of the connecting rod (211).

4. The full-automatic loading and unloading laser high-efficiency cutting system for mirror-surface stainless steel sheets as claimed in claim 1, wherein a sliding plate (170) is rotatably connected to the right side wall of the supporting frame (100), a limiting block is fixedly connected to the right side of the supporting frame (100), the limiting block is located at the bottom of the supporting frame (100), and the sliding plate (170) and the top of the conveying belt (150) are located on the same horizontal plane.

5. The full-automatic feeding and discharging laser high-efficiency cutting system for the mirror-surface stainless steel thin plate as claimed in claim 1, wherein an arc-shaped groove is formed in the top of the rotating plate (122), connecting columns are fixedly connected to the top and the bottom of the first connecting block (121), the bottom of each connecting column is fixedly connected to the top of the rotating plate (120), and the top of each connecting column is located inside the arc-shaped groove.

6. The full-automatic loading and unloading laser high-efficiency cutting system for the mirror-surface stainless steel sheets as claimed in claim 1, wherein the left and right sides of the conveyor belt (150) are rotatably connected with second rotating rods (151), and the front side of the second rotating rod (151) on the left side penetrates through the support frame (100) and is connected with a rotating wheel.

7. The full-automatic loading and unloading laser high-efficiency cutting system for the mirror-surface stainless steel sheets as claimed in claim 6, wherein the outer walls of the rotating plate (122) and the pushing plate (130) are connected with supporting rods, the top of the supporting frame (100) is fixedly connected with a fixed block, and the supporting rods are slidably connected to the inner sides of the fixed block.

8. The full-automatic loading and unloading laser high-efficiency cutting system for the mirror-surface stainless steel sheets as claimed in claim 1, wherein the left and right sides of the bottom of the support frame (100) are fixedly connected with limit blocks, and the fifth rotating rod (230) and the sixth rotating rod (250) are rotatably connected in the limit blocks.

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