CN216207968U - Fiber fabric cutting machine - Google Patents

Abstract

A fiber fabric cutting machine comprises a workbench, a cutting mechanism, a driving mechanism and a pressing plate, wherein the workbench is used for placing fiber fabrics to be cut; the cutting mechanism can move back and forth on the workbench to cut the fiber fabric and comprises a cross beam which can move back and forth on the workbench, a blade assembly which is rotatably arranged on the cross beam and is opposite to the top surface of the workbench, and a rotating member which is arranged in the workbench and connected with and drives the blade assembly to rotate; the driving mechanism is arranged in the workbench and connected with and drives the cross beam to move back and forth; the clamp plate sets up and is used for the fixed fibre surface fabric of treating cutting on the workstation, moves through the crossbeam and drives blade subassembly and remove along certain orbit, cuts the fibre surface fabric of placing on the workstation, reduces the error that the manual work cut, improves follow-up experimental accuracy, improves the efficiency that cuts simultaneously, and then improves experimental efficiency.

Description

Fiber fabric cutting machine

Technical Field

The utility model belongs to the field of textile detection, and particularly relates to a fiber fabric cutting machine.

Background

When a laboratory detects a standard fabric, the standard fabric needs to be cut into a plurality of fabrics to be detected; at present, the actual situation of a laboratory is that scissors are manually used for cutting, the whole roll of fabric needs to be unfolded, a cut finished product cannot be well controlled to be in a required size, test errors are easily caused, the accuracy of a test result is influenced, the required time is long, the detection efficiency is influenced, and the detection efficiency needs to be further improved.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art and provides a fiber fabric cutting machine capable of reducing experimental errors.

The utility model adopts the following technical scheme:

a fiber fabric cutting machine comprises a workbench, a cutting mechanism, a driving mechanism and a pressing plate, wherein the workbench is used for placing fiber fabrics to be cut; the cutting mechanism can move back and forth on the workbench to cut the fiber fabric and comprises a cross beam which can move back and forth on the workbench, a blade assembly which is rotatably arranged on the cross beam and is opposite to the top surface of the workbench, and a rotating member which is arranged in the cross beam and is connected with the blade assembly and drives the blade assembly to rotate; the driving mechanism is arranged in the workbench and connected with and drives the cross beam to move back and forth; the pressing plate is arranged on the workbench and used for fixing the fiber fabric to be cut.

The device further comprises a proximity switch arranged on the beam and used for detecting the position of the pressing plate and a controller arranged on the workbench and connected with the proximity switch, wherein the controller is connected with the driving mechanism, processes signals fed back by the proximity switch and controls the action of the beam according to a processing result.

Furthermore, the driving mechanism comprises a rack arranged in the workbench and extending along the moving direction of the beam, a gear in running fit with the rack, a driving motor driving the gear to rotate, and a connecting rod with one end connected with the driving motor and the other end extending upwards and connected with the beam.

Furthermore, actuating mechanism still including set up in the workstation along the slide rail that the crossbeam moving direction extends, slidable sets up the slider on the slide rail and set up the motor mounting panel that is used for installing driving motor on the slider, connecting rod one end mounting panel is connected the other end and is upwards extended and be connected with the crossbeam.

Further, the workstation is including forming its inside installation cavity that is used for the installation rack, slide rail and from workstation top surface downwardly extending and installation cavity intercommunication supply the bar hole that the connecting rod stretches out.

Further, the workbench further comprises a storage cavity formed at the bottom of the installation cavity and used for storing the fiber fabric to be cut and a cabinet door used for closing or opening the storage cavity.

Further, the blade assembly comprises a rotating shaft and a plurality of blades arranged on the rotating shaft at intervals.

Furthermore, the rotating part comprises a rotating motor arranged in the cross beam and connected with one end of the rotating shaft and a bearing arranged in the cross beam and connected with the other end of the rotating shaft.

Furthermore, a placing groove for placing fiber fabrics is arranged on the workbench, and the pressing plate comprises a first section which can be embedded into the placing groove, a second section which is connected with the first section and supported on the workbench, and a plurality of first knife grooves which are arranged on the pressing plate and extend along the moving direction of the cross beam and can be opposite to the plurality of blades.

Further, a plurality of second knife grooves opposite to the plurality of first knife grooves are arranged in the placing groove.

As can be seen from the above description of the present invention, compared with the prior art, the beneficial effects of the present invention are: this application moves through the crossbeam and drives blade subassembly and remove along certain orbit, cuts the fibre surface fabric of placing on the workstation, reduces the error that the manual work cut, improves follow-up experimental accuracy, once cuts simultaneously. A plurality of fabrics to be tested can be obtained, so that the cutting efficiency is improved, and the testing efficiency is further improved; the pressing plate is arranged on the workbench to fix the fiber fabric so as to ensure the working stability of the blade assembly;

be provided with the proximity switch who detects the clamp plate position on the crossbeam, when transversely driving the blade and removing to the fibre surface fabric, when proximity switch detected the clamp plate and breaks away from the fibre surface fabric, give the controller with the signal feedback, the signal control actuating mechanism stop work of controller according to proximity switch feedback to make the crossbeam stop moving, stability when the guarantee equipment operation has improved cutting efficiency and accuracy nature simultaneously.

Drawings

FIG. 1 is a first schematic structural diagram of the present invention;

FIG. 2 is a second schematic structural view of the present invention;

FIG. 3 is a first top view of the present invention;

FIG. 4 is a second top view of the present invention;

FIG. 5 is a schematic view of the platen;

FIG. 6 is an enlarged view taken at A in FIG. 2;

in the figure, 1-workbench, 2-cutting mechanism, 3-driving mechanism, 4-pressing plate, 5-proximity switch, 6-controller, 11-placing groove, 12-cabinet door, 13-installation cavity, 14-strip hole, 15-second knife groove, 21-beam, 22-blade component, 221-rotating shaft, 222-blade, 23-rotating motor, 24-bearing, 31-rack, 32-gear, 33-driving motor, 34-sliding rail, 35-sliding block, 36-motor mounting plate, 37-connecting rod, 41-first section, 42-second section and 43-first knife groove.

Detailed Description

The utility model is further described below by means of specific embodiments.

Referring to fig. 1 to 6, a cutting machine for fiber fabric comprises a workbench 1, a cutting mechanism 2, a driving mechanism 3, a pressing plate 4, a proximity switch 5 and a controller 6.

The workbench 1 is used for placing fiber fabric to be cut, and specifically, the workbench 1 comprises a placing groove 11 extending downwards from the top surface thereof and used for placing the fiber fabric, a storage cavity arranged below the placing groove 11 and used for storing the fiber fabric to be cut, and a cabinet door 12 used for closing or opening the storage cavity.

The cutting mechanism 2 can move back and forth on the workbench 1 to cut the fiber fabric, and comprises a cross beam 21 which can move back and forth on the workbench 1, a blade assembly 22 which is rotatably arranged on the cross beam 21 and is opposite to the top surface of the workbench 1, and a rotating piece which is arranged in the cross beam 21 and is connected with and drives the blade assembly 22 to rotate.

The blade assembly 22 comprises a rotating shaft 221 which is rotatably arranged in the beam 21 and a plurality of blades 222 which are arranged on the rotating shaft 221 at intervals, and when the blade assembly is in work, the distance between two adjacent blades 222 can be adjusted according to the test requirement so as to cut fiber fabrics with different sizes at different positions to meet the test requirement; the rotating shaft 221 drives the plurality of blades 222 to rotate, so that the fabric is cut, the manual cutting error is reduced, the test accuracy is improved, the cutting efficiency is improved, and the detection efficiency is improved.

The rotation member includes a rotation motor 23 provided in the cross beam 21 to be connected to one end of the rotation shaft 221 and a bearing 24 provided in the cross beam 21 to be connected to the other end of the rotation shaft 221.

The driving mechanism 3 is arranged in the workbench 1, is connected with and drives the beam 21 to move back and forth, and comprises a rack 31 arranged in the workbench 1 and extending along the moving direction of the beam 21, a gear 32 in running fit with the rack 31, a driving motor 33 for driving the gear 32 to rotate, a slide rail 34 arranged on the workbench 1 and extending along the moving direction of the beam 21, a slide block 35 slidably arranged on the slide rail 34, a motor mounting plate 36 arranged on the slide block 35 and used for mounting the driving motor 33, and a connecting rod 37 with one end connected with the mounting plate 36 and the other end extending upwards and connected with the beam 21; the driving gear 32 rotates through the driving motor 33 and is matched with the rack 31 to drive the connecting rod 37 to move so as to drive the cross beam 21 to move; correspondingly, the workbench 1 further comprises a mounting cavity 13 formed in the workbench 1 for mounting the rack 31 and the slide rail 34, and a strip-shaped hole 37 extending downwards from the top surface of the workbench 1 and communicated with the mounting cavity 13 for the connection rod 37 to extend out.

The pressing plate 4 is arranged on the workbench 1 and used for fixing the fiber fabric to be cut, and comprises a first section 41 which can be embedded into the placing groove 11, a second section 42 which is connected with the first section 41 and supported on the workbench 1, and a plurality of first knife grooves 43 which are arranged on the second section 41 and can be opposite to the plurality of blades 222 along the moving direction of the cross beam, specifically, the area of the first section 41 is smaller than that of the second section 42, the fiber fabric is fixed through the pressing plate 4 and then matched with the first knife grooves 43 through the blades 222, so that the fiber fabric in the placing groove 11 is cut; further, a plurality of second sipes 15 are provided in the placement groove 11 opposite to the plurality of first sipes 43, and the second sipes 15 extend downward from the bottom surface of the placement groove 11.

The proximity switch 5 is arranged on the cross beam 31 and used for detecting the position of the pressing plate 4 so as to determine that the pressing plate 4 presses and fixes the fiber fabric in the placing groove 11; specifically, two proximity switches 5 are provided, and the two proximity switches 5 are oppositely disposed at two ends of the beam 21.

The controller 6 is respectively connected with the driving motor 33, the rotating motor 23 and the proximity switch 5, processes signals fed back by the proximity switch 5 and controls the action of the beam 21 according to the processing result; when the beam 21 drives the blade 222 to move towards the fiber fabric and the proximity switch 5 detects that the pressing plate 4 is separated from the fiber fabric, a signal is fed back to the controller 6, the controller 6 controls the driving motor 33 and the rotating motor 23 to stop working according to the signal fed back by the proximity switch 5, so that the beam 21 stops moving, the stability of the equipment in operation is guaranteed, and the cutting efficiency and the accuracy are improved; specifically, the controller 6 is a single chip microcomputer.

This device drives a plurality of blades 222 through rotating motor 23 and rotates, and crossbeam 21 removes and drives a plurality of blades 222 and remove along certain orbit, then cuts the fibre surface fabric of placing on workstation 1, reduces the error that the manual work cut, improves follow-up experimental accuracy, and a plurality of blades rotate simultaneously, once cut, can obtain the required experimental surface fabric of polylith, improve the efficiency of cutting, and then improve experimental efficiency.

The above description is only a preferred embodiment of the present invention, and therefore should not be taken as limiting the scope of the utility model, which is defined by the appended claims and their equivalents and modifications within the scope of the description.

Claims (10)

1. The utility model provides a fibre surface fabric guillootine which characterized in that: the cutting device comprises a workbench, a cutting mechanism, a driving mechanism and a pressing plate, wherein the workbench is used for placing fiber fabric to be cut; the cutting mechanism can move back and forth on the workbench to cut the fiber fabric and comprises a cross beam which can move back and forth on the workbench, a blade assembly which is rotatably arranged on the cross beam and is opposite to the top surface of the workbench, and a rotating member which is arranged in the cross beam and is connected with the blade assembly and drives the blade assembly to rotate; the driving mechanism is arranged in the workbench and connected with and drives the cross beam to move back and forth; the pressing plate is arranged on the workbench and used for fixing the fiber fabric to be cut.

2. A fabric cutting machine according to claim 1, characterized in that: the device comprises a worktable, a pressure plate, a proximity switch and a controller, wherein the worktable is arranged on the worktable, the pressure plate is arranged on the worktable, the controller is arranged on the worktable and is connected with the proximity switch, the controller is connected with a driving mechanism, and the controller is used for processing a signal fed back by the proximity switch and controlling the action of the crossbeam according to a processing result.

3. A fabric cutting machine according to claim 1, characterized in that: the driving mechanism comprises a rack arranged in the workbench and extending along the moving direction of the beam, a gear in running fit with the rack, a driving motor for driving the gear to rotate, and a connecting rod with one end connected with the driving motor and the other end extending upwards and connected with the beam.

4. A fabric cutting machine according to claim 3, characterized in that: the driving mechanism further comprises a sliding rail arranged in the workbench and extending along the moving direction of the cross beam, a sliding block arranged on the sliding rail in a sliding mode and a motor mounting plate arranged on the sliding block and used for mounting a driving motor, wherein one end of the connecting rod is connected with the mounting plate at one end, the other end of the connecting rod extends upwards and is connected with the cross beam.

5. A fabric guillootine of claim 4, characterized in that: the workstation is used for the installation including forming in its inside the installation cavity of rack, slide rail and follow workstation top surface downwardly extending and installation cavity intercommunication supply the bar hole that the connecting rod stretches out.

6. A fabric guillootine of claim 5, characterized in that: the workbench further comprises a storage cavity formed at the bottom of the mounting cavity and used for storing the fiber fabric to be cut and a cabinet door used for closing or opening the storage cavity.

7. A fabric cutting machine according to claim 1, characterized in that: the blade assembly comprises a rotating shaft and a plurality of blades arranged on the rotating shaft at intervals.

8. A fabric cutting machine according to claim 7, characterized in that: the rotating part comprises a rotating motor arranged in the cross beam and connected with one end of the rotating shaft and a bearing arranged in the cross beam and connected with the other end of the rotating shaft.

9. A fabric cutting machine according to claim 7, characterized in that: the workbench is provided with a placing groove for placing fiber fabrics, and the pressing plate comprises a first section which can be embedded into the placing groove, a second section which is connected with the first section and supported on the workbench, and a plurality of first knife grooves which are arranged on the pressing plate and extend along the moving direction of the cross beam and can be opposite to the plurality of blades.

10. A fabric cutting machine according to claim 9, characterized in that: the placing groove is provided with a plurality of second knife grooves opposite to the first knife grooves.

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