CN113103299B - Glass fiber cutting device capable of preventing deviation - Google Patents
Glass fiber cutting device capable of preventing deviation Download PDFInfo
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- CN113103299B CN113103299B CN202110228378.7A CN202110228378A CN113103299B CN 113103299 B CN113103299 B CN 113103299B CN 202110228378 A CN202110228378 A CN 202110228378A CN 113103299 B CN113103299 B CN 113103299B
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- block
- fixedly connected
- rod
- glass fiber
- bevel gear
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B26—HAND CUTTING TOOLS; CUTTING; SEVERING
- B26D—CUTTING; DETAILS COMMON TO MACHINES FOR PERFORATING, PUNCHING, CUTTING-OUT, STAMPING-OUT OR SEVERING
- B26D7/00—Details of apparatus for cutting, cutting-out, stamping-out, punching, perforating, or severing by means other than cutting
- B26D7/06—Arrangements for feeding or delivering work of other than sheet, web, or filamentary form
- B26D7/0608—Arrangements for feeding or delivering work of other than sheet, web, or filamentary form by pushers
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B26—HAND CUTTING TOOLS; CUTTING; SEVERING
- B26D—CUTTING; DETAILS COMMON TO MACHINES FOR PERFORATING, PUNCHING, CUTTING-OUT, STAMPING-OUT OR SEVERING
- B26D1/00—Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor
- B26D1/01—Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work
- B26D1/04—Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a linearly-movable cutting member
- B26D1/06—Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a linearly-movable cutting member wherein the cutting member reciprocates
- B26D1/08—Cutting through work characterised by the nature or movement of the cutting member or particular materials not otherwise provided for; Apparatus or machines therefor; Cutting members therefor involving a cutting member which does not travel with the work having a linearly-movable cutting member wherein the cutting member reciprocates of the guillotine type
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B26—HAND CUTTING TOOLS; CUTTING; SEVERING
- B26D—CUTTING; DETAILS COMMON TO MACHINES FOR PERFORATING, PUNCHING, CUTTING-OUT, STAMPING-OUT OR SEVERING
- B26D7/00—Details of apparatus for cutting, cutting-out, stamping-out, punching, perforating, or severing by means other than cutting
- B26D7/08—Means for treating work or cutting member to facilitate cutting
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B26—HAND CUTTING TOOLS; CUTTING; SEVERING
- B26D—CUTTING; DETAILS COMMON TO MACHINES FOR PERFORATING, PUNCHING, CUTTING-OUT, STAMPING-OUT OR SEVERING
- B26D7/00—Details of apparatus for cutting, cutting-out, stamping-out, punching, perforating, or severing by means other than cutting
- B26D7/27—Means for performing other operations combined with cutting
- B26D7/32—Means for performing other operations combined with cutting for conveying or stacking cut product
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P40/00—Technologies relating to the processing of minerals
- Y02P40/50—Glass production, e.g. reusing waste heat during processing or shaping
- Y02P40/57—Improving the yield, e-g- reduction of reject rates
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- Life Sciences & Earth Sciences (AREA)
- Forests & Forestry (AREA)
- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Re-Forming, After-Treatment, Cutting And Transporting Of Glass Products (AREA)
Abstract
The invention relates to the field of glass fibers, in particular to a glass fiber cutting device capable of preventing deviation. The technical problems to be solved by the invention are as follows: provided is a glass fiber cutting device capable of preventing occurrence of offset. The technical scheme is as follows: the glass fiber cutting device capable of preventing deviation comprises a bottom frame, a feeding component, a cutting component, a reprocessing component and a control screen; the underframe is connected with the cutting assembly; the underframe is connected with the reprocessing component; the feeding assembly is connected with the control screen; the cutting assembly is connected with the reprocessing assembly. When the glass fiber cloth roll cutting machine is used, the upper part of the loose glass fiber cloth roll is automatically compacted and then cut, so that the upper part of the cut glass fiber cloth roll is tidy, the cut glass fiber cloth roll is ejected and then the bottom of the cut glass fiber cloth roll is cut, the lower part of the cut glass fiber cloth roll is smooth, and meanwhile, the section part of the glass fiber cloth roll is not scratched in the cutting process.
Description
Technical Field
The invention relates to the field of glass fibers, in particular to a glass fiber cutting device capable of preventing deviation.
Background
Glass fiber is an inorganic nonmetallic material with excellent performance, and has the advantages of good insulativity, strong heat resistance, good corrosion resistance and high mechanical strength, but has the disadvantages of brittle property and poor wear resistance. The yarn is manufactured by taking six ores of pyrophyllite, quartz sand, limestone, dolomite, loam and boron-magnesium stone as raw materials through the processes of high-temperature melting, wire drawing, winding, weaving and the like, the diameter of a monofilament is several micrometers to twenty-several micrometers, which is equivalent to 1/20-1/5 of that of a hair, and each bundle of fiber precursor consists of hundreds or even thousands of monofilaments. Glass fibers are commonly used as reinforcing materials in composite materials, electrical and thermal insulation materials, circuit substrates, and the like in various areas of national economy.
In the prior art, one of them glass fiber yardage roll production is accomplished the back and is relatively big, need cut into the glass fiber yardage roll that the width is less earlier during the use, when cutting to the manual work, need carry out diversified fixed the cutting again to the glass fiber yardage roll, the operation process is loaded down with trivial details, and is inefficiency, simultaneously, the manual work cuts can't guarantee that the glass fiber yardage roll side that has cut is level and smooth, simultaneously, use the phenomenon that the cutting of current device can take place that the glass fiber yardage roll bottom of cutting still adheres on the glass fiber yardage roll of big, simultaneously, the glass fiber yardage roll is inside loose relatively, when current device cuts, the yardage roll upper portion can undercut a certain distance be cut again, lead to the glass fiber yardage roll upper portion of cutting completion to be uneven.
In summary, there is a need to develop a glass fiber cutting apparatus that prevents the occurrence of offset to overcome the above-mentioned problems.
Disclosure of Invention
In order to overcome among the prior art, wherein a glass fiber yardage roll is relatively big after accomplishing production, need firstly cut it into the glass fiber yardage roll that the width is less during the use, when cutting is carried out to the manual work, need carry out diversified fixing to the glass fiber yardage roll and cut again, the operation process is loaded down with trivial details, and is inefficiency, simultaneously, manual cutting can't guarantee that the glass fiber yardage roll side that cuts is smooth, simultaneously, the phenomenon that the cutting can take place that the little glass fiber yardage roll bottom that cuts still sticks on big glass fiber yardage roll still is cut to the cutting of current device, simultaneously, the glass fiber yardage roll is inside loose relatively, when current device cuts, the upper portion of yardage roll can undercut certain distance be cut again, lead to the shortcoming of the little glass fiber yardage roll upper portion unevenness that the cutting was accomplished, this invention is to solve the technical problem: provided is a glass fiber cutting device capable of preventing occurrence of offset.
The technical scheme is as follows: the glass fiber cutting device capable of preventing deviation comprises a bottom frame, a feeding component, a cutting component, a reprocessing component and a control screen; the underframe is connected with the feeding component; the underframe is connected with the cutting assembly; the underframe is connected with the reprocessing component; the feeding assembly is connected with the control screen; the cutting assembly is connected with the reprocessing assembly.
Preferably, the feeding assembly comprises a first slideway block, a first baffle, a first multi-stage hydraulic rod, a first pushing block and a first storage box; the first slideway block is fixedly connected with the first baffle; the first slideway block is fixedly connected with the first storage box; the first baffle is fixedly connected with the first multi-stage hydraulic rod; the first baffle is fixedly connected with the control screen; the first multi-stage hydraulic rod is fixedly connected with the first pushing block; the first storage box is fixedly connected with the underframe.
Preferably, the cutting assembly comprises a first motor, a first loop bar, a first prismatic bar, a first sliding block, a first electric sliding rail, a first bevel gear, a second bevel gear, a first lead screw, a second sliding block, a first guide rail block, a first pressing block, a first compacting assembly, a second pressing block, a second compacting assembly, a first driving wheel, a second loop bar, a second prismatic bar, a third sliding block, a second electric sliding rail, a third bevel gear, a fourth bevel gear, a second lead screw, a fourth sliding block, a first guide rail bar, a second guide rail bar, a third pressing block, a fourth pressing block, a first electric push rod, a first linkage block, a first cutter and a second electric push rod; the output end of the first motor is fixedly connected with the first loop bar; the lower part of the first motor is fixedly connected with the underframe; the first sleeve rod is internally connected with a first prismatic rod; the outer surface of the first sleeve rod is fixedly connected with the first driving wheel; the outer surface of the first loop bar is rotationally connected with the underframe; the outer surface of the first sleeve rod is connected with the reprocessing assembly; the outer surface of the first prismatic rod is rotationally connected with the first sliding block; the outer surface of the first prismatic rod is fixedly connected with a first bevel gear; the lower part of the first sliding block is in sliding connection with the first electric sliding rail; the lower part of the first electric sliding rail is fixedly connected with the underframe; a second bevel gear is arranged on the side edge of the first bevel gear; the inside of the second bevel gear is fixedly connected with the first screw rod; the outer surface of the first screw rod is screwed with the second sliding block; the outer surface of the first screw rod is rotationally connected with the first guide rail block; the second sliding block is in sliding connection with the first guide rail block; the second sliding block is fixedly connected with the first pressing block and the second pressing block in sequence; the first guide rail block is fixedly connected with the underframe; the first pressing block is connected with the first compacting component; the second pressing block is connected with the second compacting component; the first driving wheel is in driving connection with the second driving wheel through a belt; the inside of the second driving wheel is fixedly connected with a second loop bar; the second sleeve rod is internally connected with a second prismatic rod; the outer surface of the second sleeve rod is rotationally connected with the underframe; the outer surface of the second prismatic rod is rotationally connected with the third sliding block; the outer surface of the second prismatic rod is fixedly connected with a third bevel gear; the third sliding block is in sliding connection with the second electric sliding rail; the lower part of the second electric sliding rail is fixedly connected with the underframe; a fourth bevel gear is arranged on the side edge of the third bevel gear; the inside of the fourth bevel gear is fixedly connected with the second screw rod; the outer surface of the second screw rod is screwed with the fourth sliding block; the outer surface of the second screw rod is rotationally connected with the underframe; the inside of the fourth sliding block is in sliding connection with the first guide rail rod; the inside of the fourth sliding block is in sliding connection with the second guide rail rod; the fourth sliding block is fixedly connected with the third pressing block and the fourth pressing block in sequence; the first guide rail rod is fixedly connected with the underframe; the second guide rail rod is fixedly connected with the underframe; a first electric push rod is arranged on the side edge of the fourth pressing block; the upper part of the first electric push rod is fixedly connected with the first linkage block; the lower part of the first electric push rod is fixedly connected with the underframe; the lower part of the first linkage block is fixedly connected with the first cutter; the first linkage block is fixedly connected with the second electric push rod; the lower part of the second electric push rod is fixedly connected with the underframe.
Preferably, the first compaction assembly comprises a first connecting block, a first transmission rod, a first torsion spring, a first limiting block and a second limiting block; the first connecting block is fixedly connected with the first transmission rod; the first connecting block is fixedly connected with the first torsion spring; the first connecting block is fixedly connected with the first limiting block; the first connecting block is fixedly connected with the first pressing block; the outer surface of the first transmission rod is rotationally connected with the second limiting block; the first torsion spring is fixedly connected with the second limiting block; the first limiting block is contacted with the second limiting block.
Preferably, the reprocessing assembly comprises a third driving wheel, a fourth driving wheel, a third sleeve rod, a third prism rod, a fifth sliding block, a third electric sliding rail, a fifth bevel gear, a sixth bevel gear, a third screw rod, a sixth sliding block, a second guide rail block, a first wedge block, a second cutter, a second linkage block and a third electric push rod; the third driving wheel is in driving connection with the fourth driving wheel through a belt; the inner part of the third driving wheel is fixedly connected with the first loop bar; the inside of the fourth driving wheel is fixedly connected with a third loop bar; the inside of the third sleeve rod is connected with a third triangular rod; the outer surface of the third sleeve rod is rotationally connected with the underframe; the outer surface of the third prism is rotationally connected with the fifth sliding block; the outer surface of the third triangular pole is fixedly connected with a fifth bevel gear; the fifth sliding block is in sliding connection with the third electric sliding rail; the lower part of the third electric sliding rail is fixedly connected with the underframe; a sixth bevel gear is arranged on the side edge of the fifth bevel gear; the sixth bevel gear is fixedly connected with the third screw rod; the outer surface of the third screw rod is screwed with the sixth sliding block; the outer surface of the third screw rod is rotationally connected with the second guide rail block; the sixth sliding block is in sliding connection with the second guide rail block; the sixth sliding block is fixedly connected with the first wedge block; the second guide rail block is fixedly connected with the underframe; the inner part of the first wedge block is in sliding connection with the second cutter; the second cutter is fixedly connected with the second linkage block; the second linkage block is fixedly connected with the third electric push rod; the third electric push rod is fixedly connected with the underframe.
Preferably, two grooves are formed in the first slideway block and are respectively located below the first cutter and the first wedge block.
Preferably, the first compaction assembly is provided with a plurality of sets in a circular array.
Preferably, the second compaction assembly is provided with a plurality of sets in a circular array.
Preferably, the first cutter is located directly above the gap in the middle of the first compacting assembly and the second compacting assembly.
Compared with the prior art, the invention has the following advantages:
(1) In order to solve the prior art, wherein a glass fiber cloth roll is relatively wide after production is finished, need cut it into the glass fiber cloth roll that the width is less earlier during the use, need carry out diversified fixing to the glass fiber cloth roll when cutting by the manual work, the operation process is loaded down with trivial details, simultaneously, manual cutting can't guarantee that the glass fiber cloth roll side that cuts is smooth, simultaneously, use current device cutting can take place the phenomenon that the little glass fiber cloth roll bottom that cuts still sticks on big glass fiber cloth roll, simultaneously, glass fiber cloth roll inside is loose relatively, when current device cuts, cloth roll upper portion can undercut certain distance be cut again, lead to the uneven problem in little glass fiber cloth roll upper portion that the cutting was accomplished.
(2) The feeding assembly, the cutting assembly and the reprocessing assembly are designed; when the device is ready to work, the device is fixed on a horizontal plane, a power supply is connected, a glass fiber cloth roll to be treated is placed in a feeding component on a chassis, then a control screen control device is controlled to start to operate, the feeding component limits the glass fiber cloth roll, the glass fiber cloth roll is placed to roll, then the feeding component pushes the front end of the glass fiber cloth roll to move to the lower part of the cutting component, the cutting component downwards presses two ends of the cutting position of the glass fiber cloth roll, the glass fiber cloth roll is fixed, the glass fiber cloth is relatively loose, after extrusion, the middle part of the cutting position of the glass fiber cloth roll is raised upwards, then the cutting component compactly presses the raised part, enables the upper part of the cutting position of the glass fiber cloth roll to be relatively compact, then the cutting component cuts the glass fiber cloth roll, so that the cut upper part of the glass fiber cloth roll is neat, at the moment, the cutter cannot completely cut off the bottom of the glass fiber cloth roll, the glass fiber cloth roll is still intermittently connected together, then the feeding component pushes the glass fiber cloth roll to move, the cutting position of the glass fiber cloth roll moves to the lower part of the reprocessing component, and then the glass fiber cloth roll is cut off, and the glass fiber cloth is cut off and the fiber cloth roll is cut off.
(3) When the device is used, the upper part of the loose glass fiber cloth roll is automatically compacted and then cut, so that the upper part of the cut glass fiber cloth roll is tidy, the cut glass fiber cloth roll is jacked up and then the bottom of the cut glass fiber cloth roll is cut, the lower part of the cut glass fiber cloth roll is smooth, and meanwhile, the section part of the glass fiber cloth roll is not scratched in the cutting process.
Drawings
FIG. 1 is a schematic perspective view of a first embodiment of the present invention;
FIG. 2 is a schematic view of a second perspective structure of the present invention;
FIG. 3 is a schematic perspective view of a feeding assembly according to the present invention;
FIG. 4 is a schematic perspective view of a cutting assembly according to the present invention;
FIG. 5 is a schematic perspective view of a first portion of the cutting assembly of the present invention;
FIG. 6 is a schematic perspective view of a second portion of the cutting assembly of the present invention;
FIG. 7 is a schematic perspective view of a first compacting assembly of the present invention;
fig. 8 is a schematic perspective view of a reprocessing assembly according to the present invention.
Marked in the figure as: 1-chassis, 2-feeding assembly, 3-cutting assembly, 4-reprocessing assembly, 5-control screen, 201-first slide block, 202-first baffle, 203-first multi-stage hydraulic lever, 204-first push block, 205-first receiver, 301-first motor, 302-first loop bar, 303-first edge bar, 304-first slider, 305-first electric slide rail, 306-first bevel gear, 307-second bevel gear, 308-first lead screw, 309-second slider, 3010-first guide rail block, 3011-first press block, 3012-first compaction assembly, 3013-second press block, 3014-second compaction assembly, 3015-first drive wheel, 3016-second drive wheel, 3017-second loop bar, 3018-second edge bar, 3019-third slider, 3020-second electric slide, 3021-third bevel gear, 3022-fourth bevel gear, 3023-second lead screw, 3024-fourth slider, 3025-first rail bar, 3026-second rail bar, 3027-third press block, 3028-fourth press block, 3029-first electric push rod, 3030-first linkage block, 3031-first cutter, 3032-second electric push rod, 301201-first connection block, 301202-first transmission bar, 301203-first torsion spring, 301204-first stopper, 301205-second stopper, 401-third transmission wheel, 402-fourth transmission wheel, 403-third sleeve bar, 404-third rail bar, 405-fifth slider, 406-third electric slide rail, 407-fifth bevel gear, 408-sixth bevel gears, 409-third screw rods, 4010-sixth sliding blocks, 4011-second guide rail blocks, 4012-first wedge blocks, 4013-second cutters, 4014-second linkage blocks and 4015-third electric push rods.
Detailed Description
The following describes in detail the preferred embodiments of the present invention with reference to the accompanying drawings.
Example 1
1-8, the glass fiber cutting device capable of preventing deviation comprises a chassis 1, a feeding component 2, a cutting component 3, a reprocessing component 4 and a control screen 5; the underframe 1 is connected with the feeding component 2; the underframe 1 is connected with the cutting assembly 3; the underframe 1 is connected with the reprocessing component 4; the feeding assembly 2 is connected with the control screen 5; the cutting assembly 3 is connected to the reprocessing assembly 4.
Working principle: when the device is ready to work, the device is fixed on a horizontal plane, a power supply is connected, a glass fiber cloth roll to be treated is placed in a feeding component 2 on a chassis 1, then a control screen 5 is controlled to control the device to start to operate, the feeding component 2 limits the glass fiber cloth roll, the glass fiber cloth roll is placed to roll, then the feeding component 2 pushes the front end of the glass fiber cloth roll to move below a cutting component 3, the cutting component 3 presses down two ends of a cutting position of the glass fiber cloth roll to fix the glass fiber cloth roll, the glass fiber cloth is relatively loose, after two ends of the cutting position of the glass fiber cloth roll are extruded, the middle part of the cutting position of the glass fiber cloth roll is raised upwards, then the cutting component 3 compacts the raised part downwards, the upper part of the cutting position of the glass fiber cloth roll is relatively compact, then the cutting component 3 cuts the glass fiber cloth roll, the upper part of the cut glass fiber cloth roll is tidy, at the moment, the cutter can not completely cut off the bottom of the glass fiber cloth roll, the bottom of the glass fiber cloth roll is still connected together intermittently, then the feeding component 2 pushes the glass fiber cloth roll to move, the cut part of the glass fiber cloth roll moves to the lower part of the reprocessing component 4, then the reprocessing component 4 firstly disperses the glass fiber cloth rolls contacted with each other, then the bottom of the glass fiber cloth roll is cut off, then the feeding component 2 pushes the glass fiber cloth roll to move, and the cut glass fiber cloth roll is collected, the invention realizes that the upper part of the loose glass fiber cloth roll is automatically compacted and then cut, the upper part of the cut glass fiber cloth roll is tidy, the lower part of the cut glass fiber cloth roll is flat after the cut glass fiber cloth roll is pushed open, meanwhile, the section part of the glass fiber cloth roll is not scratched in the cutting process.
The feeding assembly 2 comprises a first slideway block 201, a first baffle 202, a first multi-stage hydraulic rod 203, a first push block 204 and a first storage box 205; the first slideway block 201 is fixedly connected with the first baffle 202; the first slideway block 201 is fixedly connected with the first storage box 205; the first baffle 202 is fixedly connected with a first multi-stage hydraulic rod 203; the first baffle 202 is fixedly connected with the control screen 5; the first multi-stage hydraulic rod 203 is fixedly connected with the first push block 204; the first storage case 205 is fixedly connected to the chassis 1.
Firstly, transversely placing a glass fiber cloth roll to be treated in a first slideway block 201, enabling one side of the glass fiber cloth roll to be in contact with a first push block 204, then pushing the first push block 204 to move by a first multi-stage hydraulic rod 203 on a first baffle 202, pushing the glass fiber cloth roll to move by the first push block 204, enabling the front end of the glass fiber cloth roll to move to the lower part of a cutting assembly 3, pushing the first push block 204 by the first push block 204 after the front end of the glass fiber cloth roll is cut off by the cutting assembly 3, enabling the cut-off part of the glass fiber cloth roll to move to the lower part of a reprocessing assembly 4, then completely cutting off the bottom of the glass fiber cloth roll by the reprocessing assembly 4, pushing the glass fiber cloth roll to move by the first push block 204, enabling the cut glass fiber cloth roll to drop into a first storage box 205, automatically limiting the glass fiber cloth roll, preventing the glass fiber cloth roll from rolling, automatically pushing the cut glass fiber cloth roll to move, and collecting the cut glass fiber cloth roll.
The cutting assembly 3 comprises a first motor 301, a first sleeve rod 302, a first prismatic rod 303, a first sliding block 304, a first electric sliding rail 305, a first bevel gear 306, a second bevel gear 307, a first lead screw 308, a second sliding block 309, a first guide rail block 3010, a first pressing block 3011, a first compacting assembly 3012, a second pressing block 3013, a second compacting assembly 3014, a first driving wheel 3015, a second driving wheel 3016, a second sleeve rod 3017, a second prismatic rod 3018, a third sliding block 3019, a second electric sliding rail 3020, a third bevel gear 3021, a fourth bevel gear 3022, a second lead screw 3023, a fourth sliding block 3024, a first guide rail rod 3025, a second guide rail rod 3026, a third pressing block 3027, a fourth pressing block 3028, a first electric push rod 3029, a first linkage block 3030, a first knife 3031 and a second electric push rod 3032; the output end of the first motor 301 is fixedly connected with a first loop bar 302; the lower part of the first motor 301 is fixedly connected with the underframe 1; the first sleeve rod 302 is internally connected with a first prismatic rod 303; the outer surface of the first sleeve rod 302 is fixedly connected with a first transmission wheel 3015; the outer surface of the first sleeve rod 302 is rotationally connected with the underframe 1; the outer surface of the first sleeve rod 302 is connected with the reprocessing component 4; the outer surface of the first prismatic rod 303 is rotationally connected with the first sliding block 304; the outer surface of the first prismatic rod 303 is fixedly connected with a first bevel gear 306; the lower part of the first sliding block 304 is in sliding connection with a first electric sliding rail 305; the lower part of the first electric sliding rail 305 is fixedly connected with the underframe 1; a second bevel gear 307 is arranged on the side of the first bevel gear 306; the inside of the second bevel gear 307 is fixedly connected with a first screw rod 308; the outer surface of the first screw rod 308 is screwed with the second sliding block 309; the outer surface of the first screw rod 308 is rotationally connected with the first guide rail block 3010; the second slide block 309 is slidably connected to the first guide block 3010; the second slide block 309 is fixedly connected with the first press block 3011 and the second press block 3013 in sequence; the first guide rail block 3010 is fixedly connected with the underframe 1; the first press block 3011 is connected to a first compaction assembly 3012; the second press block 3013 is connected to a second compaction assembly 3014; the first transmission wheel 3015 is in transmission connection with the second transmission wheel 3016 through a belt; the inside of the second transmission wheel 3016 is fixedly connected with a second loop bar 3017; the inside of the second sleeve 3017 is connected with a second edge 3018; the outer surface of the second loop bar 3017 is rotationally connected with the underframe 1; the outer surface of the second edge rod 3018 is rotationally connected with a third slide block 3019; the outer surface of the second prismatic rod 3018 is fixedly connected with a third bevel gear 3021; the third slider 3019 is slidingly connected to the second electric slide 3020; the lower part of the second electric sliding rail 3020 is fixedly connected with the underframe 1; a fourth bevel gear 3022 is arranged on the side of the third bevel gear 3021; the inside of the fourth bevel gear 3022 is fixedly connected with a second screw rod 3023; the outer surface of the second screw rod 3023 is screwed with the fourth sliding block 3024; the outer surface of the second screw rod 3023 is rotationally connected with the underframe 1; the inside of the fourth slider 3024 is slidably connected to the first rail bar 3025; the inside of the fourth sliding block 3024 is slidably connected with the second guide rail bar 3026; the fourth slider 3024 is fixedly connected with the third pressing block 3027 and the fourth pressing block 3028 in sequence; the first guide rail rod 3025 is fixedly connected with the chassis 1; the second guide rail rod 3026 is fixedly connected with the chassis 1; a first electric push rod 3029 is arranged at the side edge of the fourth pressing block 3028; the upper part of the first electric push rod 3029 is fixedly connected with a first linkage block 3030; the lower part of the first electric push rod 3029 is fixedly connected with the underframe 1; the lower part of the first linkage block 3030 is fixedly connected with a first cutter 3031; the first linkage block 3030 is fixedly connected with the second electric push rod 3032; the lower part of the second electric push rod 3032 is fixedly connected with the chassis 1.
When the feeding assembly 2 pushes the glass fiber cloth roll to the position right below the first cutting knife 3031, the first motor 301 drives the first sleeve rod 302 to drive the first driving wheel 3015 to rotate, the first driving wheel 3015 drives the second driving wheel 3016 to drive the second sleeve rod 3017 to rotate, the second sleeve rod 3017 drives the second prismatic rod 3018 to drive the third bevel gear 3021 to rotate, then the second electric sliding rail 3020 drives the third sliding block 3019 to slide towards the fourth bevel gear 3022, the third sliding block 3018 drives the second prismatic rod 3011 to move, the third bevel gear 3021 is meshed with the fourth bevel gear 3022, then the third bevel gear 3021 drives the fourth bevel gear 3022 to drive the second lead screw 3023 to rotate, the second lead screw 3023 drives the fourth sliding block 3024 to slide downwards on the first guide rail rod 3025 and the second guide rail rod 3026, the fourth sliding block 3024 drives the third pressing block 3027 and the fourth pressing block 3028 to move downwards, the third pressing block 3027 and the fourth pressing block 3028 are respectively fixed at two ends of the glass fiber cloth roll to be cut, after the two ends of the glass fiber cloth roll cutting position are extruded, the middle part of the glass fiber cloth roll cutting position is raised upwards, then the second electric sliding rail 3020 drives the third sliding block 3019 to move back to the original position, the third bevel gear 3021 and the fourth bevel gear 3022 are stopped from being meshed, then the first sleeve rod 302 drives the first prismatic rod 303 to drive the first bevel gear 306 to rotate, then the first electric sliding rail 305 drives the first sliding block 304 to slide towards the second bevel gear 307, the first sliding block 304 drives the first prismatic rod 303 to drive the first bevel gear 306 to move, the first bevel gear 306 is meshed with the second bevel gear 307, then the first bevel gear 306 drives the second bevel gear 307 to drive the first lead screw 308 to rotate, the first lead screw 308 drives the second sliding block 309 to slide downwards on the first guide rail block 3010, the second sliding block 309 drives the first pressing block 3011 and the second pressing block 3013 to move downwards, the first pressing block 3011 and the second pressing block 3013 respectively drive the first compacting component 3012 and the second compacting component 3014 to move downwards, so that the first compacting component 3012 and the second compacting component 3014 compact the raised portion downwards, the upper portion of the cut glass fiber cloth roll is relatively compact, then the first electric sliding rail 305 drives the first sliding block 304 to move back to the original position, the first bevel gear 306 and the second bevel gear 307 are stopped from being meshed, then the first electric push rod 3029 and the second electric push rod 3032 simultaneously drive the first linkage block 3030 to move downwards, the first linkage block 3030 drives the first cutter 3031 to move downwards, the first cutter 3031 cuts the glass fiber cloth roll downwards through the gap between the first compacting component 3012 and the second compacting component 3014, the cut glass fiber cloth roll is tidy, at the moment, the cutter cannot cut the bottom of the glass fiber cloth roll completely, the bottom of the glass fiber cloth roll is still connected together intermittently, then the first electric push rod 3029 and the second electric push rod 3032 simultaneously drive the first linkage block 3030 to move upwards, the first linkage block 3030 drives the first cutter 3031 to move upwards to the original position, the first motor 301 starts to rotate reversely, then the first bevel gear 306 is meshed with the second bevel gear 307, the first pressing block 3011, the first compacting component 3012, the second pressing block 3013 and the second compacting component 3014 are moved upwards to the original position, then the first bevel gear 306 is stopped from being meshed with the second bevel gear 307, meanwhile, the third bevel gear 3021 is meshed with the fourth bevel gear 3022, the third pressing block 3027 and the fourth pressing block 3028 are moved upwards to the original position, then the third bevel gear 3021 is stopped from being meshed with the fourth bevel gear 3022, and the upper part of the loose glass fiber cloth roll is compacted and cut automatically when the glass fiber cloth roll is used, and the upper part of the cut glass fiber cloth roll is tidy.
The first compaction assembly 3012 comprises a first connecting block 301201, a first transmission rod 301202, a first torsion spring 301203, a first limiting block 301204 and a second limiting block 301205; the first connecting block 301201 is fixedly connected with the first transmission rod 301202; the first connecting block 301201 is fixedly connected with the first torsion spring 301203; the first connecting block 301201 is fixedly connected with the first limiting block 301204; the first connecting block 301201 is fixedly connected with the first pressing block 3011; the outer surface of the first transmission rod 301202 is rotationally connected with the second limiting block 301205; the first torsion spring 301203 is fixedly connected with the second limiting block 301205; the first stopper 301204 contacts the second stopper 301205.
The first pressing block 3011 drives the first connecting block 301201 to move downwards, the first connecting block 301201 drives the first limiting block 301204 to drive the second limiting block 301205 to move downwards, the second limiting block 301205 compacts the raised glass fiber cloth roll, then the first cutting knife 3031 moves downwards to pass through the second limiting block 301205, at the moment, the first cutting knife 3031 pushes the second limiting block 301205 to rotate downwards around the first transmission rod 301202 for a certain angle, the first cutting knife 3031 can smoothly cut the glass fiber cloth roll through the second limiting block 301205, then the first cutting knife 3031 moves upwards to return to the original position, and the first torsion spring 301203 drives the second limiting block 301205 to move back to the original position, so that the raised glass fiber cloth roll is compacted automatically, the structure is simplified, and maintenance is simple.
The reprocessing component 4 comprises a third driving wheel 401, a fourth driving wheel 402, a third sleeve rod 403, a third prism rod 404, a fifth sliding block 405, a third electric sliding rail 406, a fifth bevel gear 407, a sixth bevel gear 408, a third screw rod 409, a sixth sliding block 4010, a second guide rail block 4011, a first wedge block 4012, a second cutter 4013, a second linkage block 4014 and a third electric push rod 4015; the third driving wheel 401 is in driving connection with the fourth driving wheel 402 through a belt; the inside of the third driving wheel 401 is fixedly connected with the first sleeve rod 302; the inside of the fourth driving wheel 402 is fixedly connected with a third loop bar 403; the third sleeve bar 403 is connected with the third triangular bar 404 inside; the outer surface of the third sleeve rod 403 is rotationally connected with the underframe 1; the outer surface of the third prism 404 is rotationally connected with a fifth sliding block 405; the outer surface of the third prism 404 is fixedly connected with a fifth bevel gear 407; the fifth sliding block 405 is in sliding connection with the third electric sliding rail 406; the lower part of the third electric sliding rail 406 is fixedly connected with the underframe 1; a sixth bevel gear 408 is arranged on the side of the fifth bevel gear 407; the sixth bevel gear 408 is fixedly connected with a third screw rod 409; the outer surface of the third screw rod 409 is screwed with a sixth sliding block 4010; the outer surface of the third screw rod 409 is rotationally connected with the second guide rail block 4011; the inside of the sixth slider 4010 is slidably connected with the second guide rail block 4011; the sixth slider 4010 is fixedly connected with the first wedge 4012; the second guide rail block 4011 is fixedly connected with the underframe 1; the inside of the first wedge 4012 is in sliding connection with a second cutter 4013; the second cutter 4013 is fixedly connected with the second linkage block 4014; the second linkage block 4014 is fixedly connected with a third electric push rod 4015; the third electric putter 4015 is fixedly connected to the chassis 1.
When the feeding component 2 conveys the cut part of the glass fiber cloth roll to the position right below the second cutter 4013, and at the moment, the glass fiber cloth roll at the cut part is still contacted with the second cutter 4013, the first loop bar 302 drives the third driving wheel 401 to drive the fourth driving wheel 402 to rotate, the fourth driving wheel 402 drives the third loop bar 403 to drive the third prism bar 404 to rotate, the third prism bar 404 drives the fifth bevel gear 407 to rotate, then the third electric sliding rail 406 drives the fifth sliding block 405 to slide towards the sixth bevel gear 408, the fifth sliding block 405 drives the third prism bar 404 to drive the fifth bevel gear 407 to move, the fifth bevel gear 407 is meshed with the sixth bevel gear 408, then the fifth bevel gear 407 drives the sixth bevel gear 408 to drive the third lead screw 409 to rotate, the third lead screw 409 drives the sixth sliding block 4010 to slide downwards on the second guide rail block 4011, the sixth sliding block 4010 drives the first wedge block 4012 to move downwards, the first wedge 4012 is inserted into a cut part of the glass fiber cloth roll, then the third electric push rod 4015 drives the second linkage block 4014 to drive the second cutter 4013 to move downwards, the second cutter 4013 cuts off the bottom of the glass fiber cloth roll completely through the inner part of the first wedge 4012, the second cutter 4013 cannot contact with the section part of the glass fiber cloth roll in the process, then the third electric push rod 4015 drives the second linkage block 4014 to drive the second cutter 4013 to move upwards to the original position, and then the first sleeve rod 302 is reversed, so that the first wedge 4012 moves upwards to the original position, and when the glass fiber cloth roll is used, the cut bottom of the cut glass fiber cloth roll is cut again, the lower part of the cut glass fiber cloth roll is flat, and meanwhile the section part of the glass fiber cloth roll cannot be scratched in the cutting process.
In the present invention, two grooves are formed in the first slideway block 201, and the two grooves are respectively located below the first cutter 3031 and the first wedge block 4012.
Interference with the first slideway block 201 when the first cutter 3031, the first wedge 4012 and the second cutter 4013 move downwards can be prevented.
The first compaction assembly 3012 is provided with a plurality of sets in a circular array, as described herein.
The raised fiberglass cloth roll may be compacted at an upper location.
The second compaction assembly 3014 is provided with multiple sets in a circular array as described herein.
The raised fiberglass cloth roll may be compacted at an upper location.
The first knife 3031 is located directly above the gap in the middle of the first and second compaction assemblies 3012 and 3014 as described in the present invention.
The first blade 3031 may be moved downward through the gap of the first and second compaction assemblies 3012 and 3014.
The foregoing is merely illustrative of the present invention, and the present invention is not limited thereto, and any person skilled in the art will readily recognize that variations or substitutions are within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.
Claims (7)
1. A glass fiber cutting device capable of preventing deviation comprises a chassis and a control screen; the device is characterized by further comprising a feeding assembly, a cutting assembly and a reprocessing assembly; the underframe is connected with the feeding component; the underframe is connected with the cutting assembly; the underframe is connected with the reprocessing component; the feeding assembly is connected with the control screen; the cutting assembly is connected with the reprocessing assembly;
the feeding assembly comprises a first slideway block, a first baffle, a first multi-stage hydraulic rod, a first pushing block and a first storage box; the first slideway block is fixedly connected with the first baffle; the first slideway block is fixedly connected with the first storage box; the first baffle is fixedly connected with the first multi-stage hydraulic rod; the first baffle is fixedly connected with the control screen; the first multi-stage hydraulic rod is fixedly connected with the first pushing block; the first storage box is fixedly connected with the underframe;
the cutting assembly comprises a first motor, a first sleeve rod, a first prismatic rod, a first sliding block, a first electric sliding rail, a first bevel gear, a second bevel gear, a first screw rod, a second sliding block, a first guide rail block, a first pressing block, a first compacting assembly, a second pressing block, a second compacting assembly, a first driving wheel, a second sleeve rod, a second prismatic rod, a third sliding block, a second electric sliding rail, a third bevel gear, a fourth bevel gear, a second screw rod, a fourth sliding block, a first guide rail rod, a second guide rail rod, a third pressing block, a fourth pressing block, a first electric push rod, a first linkage block, a first cutter and a second electric push rod; the output end of the first motor is fixedly connected with the first loop bar; the lower part of the first motor is fixedly connected with the underframe; the first sleeve rod is internally connected with a first prismatic rod; the outer surface of the first sleeve rod is fixedly connected with the first driving wheel; the outer surface of the first loop bar is rotationally connected with the underframe; the outer surface of the first sleeve rod is connected with the reprocessing assembly; the outer surface of the first prismatic rod is rotationally connected with the first sliding block; the outer surface of the first prismatic rod is fixedly connected with a first bevel gear; the lower part of the first sliding block is in sliding connection with the first electric sliding rail; the lower part of the first electric sliding rail is fixedly connected with the underframe; a second bevel gear is arranged on the side edge of the first bevel gear; the inside of the second bevel gear is fixedly connected with the first screw rod; the outer surface of the first screw rod is screwed with the second sliding block; the outer surface of the first screw rod is rotationally connected with the first guide rail block; the second sliding block is in sliding connection with the first guide rail block; the second sliding block is fixedly connected with the first pressing block and the second pressing block in sequence; the first guide rail block is fixedly connected with the underframe; the first pressing block is connected with the first compacting component; the second pressing block is connected with the second compacting component; the first driving wheel is in driving connection with the second driving wheel through a belt; the inside of the second driving wheel is fixedly connected with a second loop bar; the second sleeve rod is internally connected with a second prismatic rod; the outer surface of the second sleeve rod is rotationally connected with the underframe; the outer surface of the second prismatic rod is rotationally connected with the third sliding block; the outer surface of the second prismatic rod is fixedly connected with a third bevel gear; the third sliding block is in sliding connection with the second electric sliding rail; the lower part of the second electric sliding rail is fixedly connected with the underframe; a fourth bevel gear is arranged on the side edge of the third bevel gear; the inside of the fourth bevel gear is fixedly connected with the second screw rod; the outer surface of the second screw rod is screwed with the fourth sliding block; the outer surface of the second screw rod is rotationally connected with the underframe; the inside of the fourth sliding block is in sliding connection with the first guide rail rod; the inside of the fourth sliding block is in sliding connection with the second guide rail rod; the fourth sliding block is fixedly connected with the third pressing block and the fourth pressing block in sequence; the first guide rail rod is fixedly connected with the underframe; the second guide rail rod is fixedly connected with the underframe; a first electric push rod is arranged on the side edge of the fourth pressing block; the upper part of the first electric push rod is fixedly connected with the first linkage block; the lower part of the first electric push rod is fixedly connected with the underframe; the lower part of the first linkage block is fixedly connected with the first cutter; the first linkage block is fixedly connected with the second electric push rod; the lower part of the second electric push rod is fixedly connected with the underframe.
2. The glass fiber cutting apparatus capable of preventing deflection as recited in claim 1, wherein the first compacting assembly comprises a first connecting block, a first transmission rod, a first torsion spring, a first stopper and a second stopper; the first connecting block is fixedly connected with the first transmission rod; the first connecting block is fixedly connected with the first torsion spring; the first connecting block is fixedly connected with the first limiting block; the first connecting block is fixedly connected with the first pressing block; the outer surface of the first transmission rod is rotationally connected with the second limiting block; the first torsion spring is fixedly connected with the second limiting block; the first limiting block is contacted with the second limiting block.
3. The glass fiber cutting device capable of preventing deflection according to claim 2, wherein the reprocessing assembly comprises a third driving wheel, a fourth driving wheel, a third sleeve rod, a third prism rod, a fifth sliding block, a third electric sliding rail, a fifth bevel gear, a sixth bevel gear, a third screw rod, a sixth sliding block, a second guide rail block, a first wedge block, a second cutter, a second linkage block and a third electric push rod; the third driving wheel is in driving connection with the fourth driving wheel through a belt; the inner part of the third driving wheel is fixedly connected with the first loop bar; the inside of the fourth driving wheel is fixedly connected with a third loop bar; the inside of the third sleeve rod is connected with a third triangular rod; the outer surface of the third sleeve rod is rotationally connected with the underframe; the outer surface of the third prism is rotationally connected with the fifth sliding block; the outer surface of the third triangular pole is fixedly connected with a fifth bevel gear; the fifth sliding block is in sliding connection with the third electric sliding rail; the lower part of the third electric sliding rail is fixedly connected with the underframe; a sixth bevel gear is arranged on the side edge of the fifth bevel gear; the sixth bevel gear is fixedly connected with the third screw rod; the outer surface of the third screw rod is screwed with the sixth sliding block; the outer surface of the third screw rod is rotationally connected with the second guide rail block; the sixth sliding block is in sliding connection with the second guide rail block; the sixth sliding block is fixedly connected with the first wedge block; the second guide rail block is fixedly connected with the underframe; the inner part of the first wedge block is in sliding connection with the second cutter; the second cutter is fixedly connected with the second linkage block; the second linkage block is fixedly connected with the third electric push rod; the third electric push rod is fixedly connected with the underframe.
4. A glass fiber cutting apparatus capable of preventing deflection according to claim 3, wherein the first slide block is internally provided with two grooves, and the two grooves are respectively positioned below the first cutter and the first wedge block.
5. A deflection-preventing glass fiber cutting apparatus according to claim 4, wherein the first compacting member is provided in a circular array of plural groups.
6. A deflection-preventing glass fiber cutting apparatus according to claim 5, wherein the second compacting members are arranged in a circular array of groups.
7. A glass fiber cutting apparatus as in claim 6 wherein the first cutter is positioned directly above the gap between the first compacting member and the second compacting member.
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| CN202110228378.7A CN113103299B (en) | 2021-03-02 | 2021-03-02 | Glass fiber cutting device capable of preventing deviation |
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| CN207127935U (en) * | 2017-05-27 | 2018-03-23 | 吕欣雨 | A kind of plastic pipe high efficiency cutter device |
| CN107160449A (en) * | 2017-07-21 | 2017-09-15 | 湖南丹尼尔智能科技有限公司 | A kind of root shape Chinese medicinal material cutter device |
| KR102181314B1 (en) * | 2019-05-15 | 2020-11-20 | 주식회사 와이아이이엔지 | Cutting apparatus for glass fiber rebar |
| CN211891015U (en) * | 2020-03-18 | 2020-11-10 | 山东麦肯金属材料有限公司 | Paper roll cutting machine for aluminum roll |
| CN112297075A (en) * | 2020-10-20 | 2021-02-02 | 张浩强 | MPP cable protection pipe cutting device |
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Effective date of registration: 20230619 Address after: 266000 Shanghe international trade building, No.2, Changjiang 1st Road, Shanghe demonstration zone, Jiaozhou City, Qingdao City, Shandong Province Applicant after: QINGDAO GUDE COMPOSITES TECHNOLOGY CO.,LTD. Address before: Room 802, unit 2, building 3, Fortune Center, Gaoxin Third Road, high tech Zone, Xi'an, Shaanxi 710000 Applicant before: Huang Yunmei |
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