CN216583302U - Rupture membrane production coiling mechanism convenient to get material - Google Patents

Abstract

The utility model relates to an rupture membrane production technical field discloses an rupture membrane production coiling mechanism convenient to get material, include base, hold-in range, rolling subassembly, get and put subassembly and going the electrical component, the base is concave type structure setting, the rolling subassembly is the interval with going the electrical component and sets up in the base, and the inner wall that rolling subassembly and going the electrical component all run through the base and outwards extend, the hold-in range is located the side of base, and the hold-in range cover is established on rolling subassembly and going the electrical component, get to put the subassembly and slide and set up on the lateral wall of base, and get to put the subassembly and peg graft mutually with the rolling subassembly. The utility model has the advantages that: through the rolling assembly, the explosion-proof membrane can be easily fixed on the rolling assembly to carry out rolling work, and the assembly is taken and put to the rethread for the explosion-proof membrane after the rolling is accomplished can be taken off very conveniently, has improved work efficiency.

Description

Rupture membrane production coiling mechanism convenient to get material

Technical Field

The application relates to the technical field of rupture membrane production, in particular to a rupture membrane production winding device convenient for material taking.

Background

The explosion-proof membrane is a layer of thin film which is arranged on a display screen of a digital product or a front windshield of an automobile, has extremely high requirement on light transmission, and has much higher price than that of a common membrane. The current explosion-proof membrane is generally composed of a plurality of base layers, and the base layers are bonded by optical glue. There is certain drawback in the equipment of current production rupture membrane when using, and in the production process, the rupture membrane needs the staff to say that the rupture membrane twines many rings on the wind-up roll and just can make the rupture membrane fix on the wind-up roll when the rolling, but this kind of operating mode is after the rolling is accomplished, and the rupture membrane is taken off by the wind-up roll and just becomes very loaded down with trivial details, wastes time and energy.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides an rupture membrane production coiling mechanism convenient to get material, include base, hold-in range, rolling subassembly, get and put subassembly and going electric assembly, the base is concave type structure setting, the rolling subassembly is the interval with going electric assembly and sets up in the base, and the inner wall that rolling subassembly and going electric assembly all run through the base and outwards extend, the hold-in range is located the side of base, and the hold-in range cover is established on rolling subassembly and going electric assembly, get to put the subassembly and slide and set up on the lateral wall of base, and get to put the subassembly and peg graft mutually with the rolling subassembly.

Further, the rolling component comprises an L-shaped seat, a rolling motor, a rotating barrel frame, a sliding arc plate, a sliding handle and a plurality of telescopic springs, the rotating barrel frame is horizontally arranged between the base and the taking and placing component, one end of the rotating barrel frame penetrates through the base and extends outwards, the other end of the rotating barrel frame is inserted with the taking and placing component, the L-shaped seat is arranged on the side wall of the base, the rolling motor is arranged on the side wall of the L-shaped seat, the output end of the rolling motor penetrates through the L-shaped seat and is connected with the rotating barrel frame, the sliding arc plate is arranged in the rotating barrel frame in a sliding mode, L-shaped arc grooves for sliding of two ends of the sliding arc plate are formed in two inner walls of the rotating barrel frame, the sliding handle is arranged at the other end of the rotating barrel frame, the sliding handle penetrates through the rotating barrel frame and is connected with the sliding arc plate, and each telescopic spring is arranged on one side wall of the sliding arc plate at equal intervals, and each telescopic spring is connected with the inner wall of the rotary barrel frame, a gap for fixing the explosion-proof membrane is arranged between the other side wall of the sliding arc plate and the rotary barrel frame, and a notch for taking out the explosion-proof membrane is formed in the outer wall of the rotary barrel frame.

Further, the taking and placing assembly comprises a taking and placing plate, a T-shaped sliding block, an L-shaped frame, an inserting block, a transverse plate, a connecting block, a treading frame and two compression springs, an air opening is formed in the side wall of the base, the taking and placing plate is vertically positioned at the air opening, the T-shaped sliding block is arranged on the side wall of the taking and placing plate, a T-shaped groove for the T-shaped sliding block to slide is formed in the side wall of the base, the T-shaped sliding block is positioned in the T-shaped groove, the L-shaped frame is arranged at the bottom of the base and positioned below the taking and placing plate, the inserting block is inserted into the bottom of the taking and placing plate, the transverse plate is arranged at the bottom of the inserting block, the two compression springs are arranged at the bottom of the transverse plate at intervals, the bottom of each compression spring is connected with the L-shaped frame, the connecting block is arranged at the bottom of the transverse plate and positioned between the two compression springs, the bottom of the connecting block penetrates through the L-shaped frame and extends downwards, the treading frame is arranged at the bottom of the connecting block, and the rotating barrel frame is connected with the taking and placing plate in an inserting mode.

Further, the de-electrifying assembly comprises a bearing table, a dryer, a de-electrifying roller and a flattening roller, the bearing table is arranged on the inner bottom wall of the base, the dryer is arranged at the top of the base, the dryer is positioned right above the bearing table, the de-electrifying roller and the flattening roller are horizontally positioned in the base at intervals, one ends of the de-electrifying roller and the flattening roller are rotatably connected with the inner wall of one side of the base, the other ends of the de-electrifying roller and the flattening roller penetrate through the inner wall of the other side of the base and extend outwards, the de-electrifying roller and the flattening roller are respectively positioned at the two sides of the dryer, the synchronous belt is sleeved on the output ends of the electricity removing roller, the flattening roller and the winding motor, a cavity is arranged inside the electricity removing roller, the blanking device is characterized in that a plurality of blanking holes which are arranged at equal intervals are formed in the outer wall of the de-electrifying roller, the outer wall of the de-electrifying roller is sleeved with a sponge sleeve, and the outer wall of the flattening roller is sleeved with a cotton cloth sleeve.

Furthermore, a handle is arranged on the outer wall of the taking and placing plate.

Furthermore, an injection port is formed in the outer wall of the de-electrifying roller, a plug is inserted into the outer wall of the de-electrifying roller, and the plug is positioned in the injection port.

The embodiment of the application adopts at least one technical scheme which can achieve the following beneficial effects:

firstly, when the winding operation is carried out, one end of the explosion-proof membrane passes through the de-electrifying assembly and is pulled to the rotating barrel frame, then the taking and placing assembly is opened, the sliding handle is exposed, the sliding handle slides along the L-shaped arc groove to drive the sliding arc plate to slide in the rotating barrel frame, a plurality of expansion springs are compressed, the distance between the sliding arc plate and the rotating barrel frame is enlarged, one end of the explosion-proof membrane is placed in the gap between the sliding arc plate and the rotating barrel frame, then the sliding handle slides reversely along the L-shaped arc groove to reduce the distance between the sliding arc plate and the rotating barrel frame, the elastic potential energy of the expansion springs is utilized to clamp one end of the explosion-proof membrane between the rotating barrel frame and the sliding arc plate, the taking and placing assembly is closed, the driving motor rotates to carry out the winding operation, after the winding operation is finished, the taking and placing assembly is opened, the sliding handle slides to enlarge the distance between the rotating barrel frame and the sliding arc plate, the clamping of the explosion-proof film is loosened, and the explosion-proof film roll is pushed along the direction of the groove in the rotating barrel frame, so that the explosion-proof film roll can be easily taken down from the rotating barrel frame through the groove, the operation is simple, and the working efficiency is improved.

Secondly, when the winding motor drives the rotating barrel frame to rotate and drive the explosion-proof membrane to move, the de-electrifying roller and the flattening roller are also driven to rotate through the connection of the synchronous belt to assist the explosion-proof membrane to move and contact with the explosion-proof membrane, softener is injected into the de-electrifying roller, the softener soaks the sponge sleeve through a plurality of blanking holes, the softener is coated on the explosion-proof membrane through the sponge sleeve to remove static electricity on the explosion-proof membrane, then the explosion-proof membrane moves to a dryer, the softener on the explosion-proof membrane is dried by the dryer, then the explosion-proof membrane moves to a flattening roller, the anti-explosion film is wiped by the cotton cloth sleeve on the flattening roller, thereby avoiding the softener remaining on the anti-explosion film, simultaneously through the setting of flattening roller, destatic roller and plummer, can roll the rupture membrane flat, avoid the rupture membrane bubble to appear in the rolling engineering, lead to the condition appearance that the quality of rupture membrane book reduces.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the application and together with the description serve to explain the application and not to limit the application. In the drawings:

fig. 1 is a schematic perspective view of the present invention;

fig. 2 is an exploded schematic view of the three-dimensional structure of the winding assembly of the present invention;

FIG. 3 is an enlarged view taken at A in FIG. 2;

fig. 4 is a schematic perspective view of the pick-and-place assembly of the present invention;

FIG. 5 is a schematic view of a partial three-dimensional structure of the present invention;

fig. 6 is an exploded view of the local three-dimensional structure of the de-electrifying assembly of the present invention.

In the figure: the device comprises a base 1, a synchronous belt 2, a winding component 3, an L-shaped seat 31, a winding motor 32, a rotating barrel frame 33, a sliding arc plate 34, a sliding handle 35, a telescopic spring 36, a taking and placing component 4, a taking and placing plate 41, a T-shaped sliding block 42, an L-shaped frame 43, an inserting block 44, a transverse plate 45, a connecting block 46, a stepping frame 47, a compression spring 48, a handle 49, a power-off component 5, a bearing platform 51, a dryer 52, a power-off roller 53, a flattening roller 54, a sponge sleeve 55, a cotton cloth sleeve 56 and a plug 57.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the technical solutions of the present application will be described in detail and completely with reference to the following specific embodiments of the present application and the accompanying drawings. It should be apparent that the described embodiments are only some of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

The technical solutions provided by the embodiments of the present application are described in detail below with reference to the accompanying drawings.

This embodiment, as shown in fig. 1 to 6, an rupture membrane production coiling mechanism convenient to get material, include base 1, hold-in range 2, rolling component 3, get and put subassembly 4 and going electric component 5, base 1 is concave type structure setting, rolling component 3 is the interval with going electric component 5 and sets up in base 1, and rolling component 3 and going electric component 5 all run through base 1's inner wall and outwards extend, hold-in range 2 is located base 1's side, and hold-in range 2 cover establish on rolling component 3 and going electric component 5, get to put subassembly 4 and slide and set up on base 1's lateral wall, and get to put subassembly 4 and peg graft mutually with rolling component 3.

Specifically, the winding assembly 3 comprises an L-shaped seat 31, a winding motor 32, a rotating barrel holder 33, a sliding arc plate 34, a sliding handle 35 and a plurality of extension springs 36, the rotating barrel holder 33 is horizontally positioned between the base 1 and the taking and placing assembly 4, one end of the rotating barrel holder 33 penetrates through the base 1 and extends outwards, the other end of the rotating barrel holder 33 is inserted into the taking and placing assembly 4, the L-shaped seat 31 is arranged on the side wall of the base 1, the winding motor 32 is arranged on the side wall of the L-shaped seat 31, the output end of the winding motor 32 penetrates through the L-shaped seat 31 and is connected with the rotating barrel holder 33, the sliding arc plate 34 is slidably arranged in the rotating barrel holder 33, two inner walls of the rotating barrel holder 33 are respectively provided with L-shaped arc grooves for sliding at two ends of the sliding arc plate 34, the sliding handle 35 is positioned at the other end of the rotating barrel holder 33, and the sliding handle 35 penetrates through the rotating barrel holder 33 and is connected with the sliding arc plate 34, each telescopic spring 36 is arranged on one side wall of the sliding arc plate 34 at equal intervals, each telescopic spring 36 is connected with the inner wall of the rotating barrel frame 33, a gap for fixing an explosion-proof membrane is arranged between the other side wall of the sliding arc plate 34 and the rotating barrel frame 33, a slot for taking out the explosion-proof membrane is arranged on the outer wall of the rotating barrel frame 33, when the winding is carried out, one end of the explosion-proof membrane penetrates through the power-off component 5 and is pulled to the rotating barrel frame 33, then the taking and placing component 4 is opened, the sliding handle 35 is exposed, the sliding handle 35 slides along the L-shaped arc groove to drive the sliding arc plate 34 to slide in the rotating barrel frame 33, a plurality of telescopic springs 36 are compressed, the interval between the sliding arc plate 34 and the rotating barrel frame 33 is enlarged, one end of the explosion-proof membrane is placed in the gap between the sliding arc plate 34 and the rotating barrel frame 33, then the sliding handle 35 reversely slides along the L-shaped arc groove, reduce the interval between slip arc 34 and the rotation bobbin cradle 33, and through the elastic potential energy of a plurality of expanding spring 36, can be with the one end centre gripping of rupture membrane between rotation bobbin cradle 33 and slip arc 34, close and get and put subassembly 4, drive rolling motor 32 rotates, can carry out rolling work, after the rolling is accomplished, open and get and put subassembly 4, slip handle 35, enlarge the interval between rotation bobbin cradle 33 and the slip arc 34, loosen the centre gripping to the rupture membrane, promote the rupture membrane book along the direction of rotating the fluting on the bobbin cradle 33, thereby can make the rupture membrane book easily take off on by rotating bobbin cradle 33 through the fluting, and the operation is simple, and the work efficiency is improved.

Specifically, the pick-and-place assembly 4 includes a pick-and-place plate 41, a T-shaped slider 42, an L-shaped frame 43, an insertion block 44, a transverse plate 45, a connecting block 46, a stepping frame 47 and two compression springs 48, an air opening is formed in a side wall of the base 1, the pick-and-place plate 41 is vertically located at the air opening, the T-shaped slider 42 is disposed on the side wall of the pick-and-place plate 41, a T-shaped groove for the T-shaped slider 42 to slide is formed in the side wall of the base 1, the T-shaped slider 42 is located in the T-shaped groove, the L-shaped frame 43 is disposed at the bottom of the base 1, the L-shaped frame 43 is located below the pick-and-place plate 41, the insertion block 44 is inserted into the bottom of the pick-and-place plate 41, the transverse plate 45 is disposed at the bottom of the insertion block 44, the two compression springs 48 are disposed at the bottom of the transverse plate 45 at intervals, the bottom of each compression spring 48 is connected with the L-shaped frame 43, the connecting block 46 is disposed at the bottom of the transverse plate 45, and the connecting block 46 is located between two compression springs 48, the bottom of the connecting block 46 penetrates through the L-shaped frame 43 and extends downwards, the stepping frame 47 is arranged at the bottom of the connecting block 46, the rotary barrel frame 33 is inserted with the taking and placing plate 41, when the taking and placing assembly 4 is to be opened, a worker steps on and presses the stepping frame 47 with feet, the transverse plate 45 is driven to press downwards through the connection of the connecting block 46, the two compression springs 48 are compressed, the transverse plate 45 presses downwards to drive the inserting block 44 to press downwards, so that the inserting block 44 is separated from the taking and placing plate 41, then the taking and placing plate 41 is grasped and pulled outwards, the T-shaped sliding block 42 is driven to slide in the T-shaped groove until the taking and placing plate 41 cannot be pulled outwards, then the taking and placing plate 41 is pushed along the length direction of the T-shaped groove, and the sliding handle 35 is exposed, so as to perform subsequent work.

Specifically, the electricity removing assembly 5 comprises a bearing table 51, a dryer 52, an electricity removing roller 53 and a flattening roller 54, the bearing table 51 is arranged on the inner bottom wall of the base 1, the dryer 52 is arranged at the top of the base 1, the dryer 52 is positioned right above the bearing table 51, the electricity removing roller 53 and the flattening roller 54 are horizontally spaced and positioned in the base 1, one ends of the electricity removing roller 53 and the flattening roller 54 are respectively and rotatably connected with the inner wall of one side of the base 1, the other ends of the electricity removing roller 53 and the flattening roller 54 respectively penetrate through the inner wall of the other side of the base 1 and extend outwards, the electricity removing roller 53 and the flattening roller 54 are respectively positioned at two sides of the dryer 52, the synchronous belt 2 is sleeved on the output ends of the electricity removing roller 53, the flattening roller 54 and the winding motor 32, a cavity is arranged inside the electricity removing roller 53, a plurality of blanking holes which are arranged at equal intervals are arranged on the outer wall of the electricity removing roller 53, the outer wall of the de-electrifying roller 53 is sleeved with a sponge sleeve 55, the outer wall of the flattening roller 54 is sleeved with a cotton cloth sleeve 56, when the winding motor 32 drives the rotating barrel frame 33 to rotate and drive the explosion-proof film to move, the de-electrifying roller 53 and the flattening roller 54 are also driven to rotate through the connection of the synchronous belt 2, the explosion-proof film is assisted to move and contact with the explosion-proof film, a softener is injected into the de-electrifying roller 53, the softener soaks the sponge sleeve 55 through a plurality of blanking holes, the softener is smeared on the explosion-proof film through the sponge sleeve 55 to remove static electricity on the explosion-proof film, then the explosion-proof film moves to the dryer 52, the softener on the explosion-proof film is dried through the dryer 52, then the explosion-proof film moves to the flattening roller 54, the cotton cloth sleeve 56 on the flattening roller 54 wipes the explosion-proof film to avoid the softener remaining on the explosion-proof film, and meanwhile, the flattening roller 54, the de-electrifying roller 53 and the bearing platform 51 are arranged, can roll the rupture membrane flat, avoid the rupture membrane bubble to appear in the rolling engineering, lead to the condition appearance that the quality of rupture membrane book reduces.

Specifically, the handle 49 is installed on the outer wall of the taking and placing plate 41, and the movement of the taking and placing plate 41 is facilitated due to the arrangement of the handle 49.

Specifically, an injection port is formed in the outer wall of the de-electrifying roller 53, a plug 57 is inserted into the outer wall of the de-electrifying roller 53, the plug 57 is located in the injection port, and the plug 57 is pulled out, so that the softener can be injected into the de-electrifying roller 53 through the injection port.

The working process of the embodiment of the application is as follows: when the winding operation is carried out, one end of the explosion-proof membrane passes through the electricity removing component 5 and is pulled to the position of the rotating barrel frame 33, then a worker steps on and presses down the stepping frame 47 by feet, the transverse plate 45 is driven to press down through the connection of the connecting block 46, the two compression springs 48 are compressed, the transverse plate 45 presses down to drive the inserting block 44 to press down, the inserting block 44 is separated from the taking and releasing plate 41, then the handle 49 on the taking and releasing plate 41 is grasped and pulled outwards, the T-shaped sliding block 42 is driven to slide in the T-shaped groove until the taking and releasing plate 41 can not be pulled outwards, then the taking and releasing plate 41 is pushed along the length direction of the T-shaped groove, the sliding handle 35 is exposed, the sliding handle 35 along the L-shaped arc groove drives the sliding arc plate 34 to slide in the rotating barrel frame 33, the plurality of telescopic springs 36 are compressed, the distance between the sliding arc plate 34 and the rotating barrel frame 33 is enlarged, one end of the explosion-proof membrane is placed in the gap between the sliding arc plate 34 and the rotating barrel frame 33, then, the sliding handle 35 is reversely slid along the L-shaped arc groove, the distance between the sliding arc plate 34 and the rotating barrel frame 33 is reduced, and through the elastic potential energy of a plurality of extension springs 36, one end of the explosion-proof film can be clamped between the rotating barrel frame 33 and the sliding arc plate 34, the taking-and-placing plate 41 is closed, when the winding motor 32 drives the rotating barrel frame 33 to rotate and drive the explosion-proof film to move, through the connection of the synchronous belt 2, the de-electrifying roller 53 and the flattening roller 54 are also driven to rotate, the explosion-proof film is assisted to move and contact with the explosion-proof film, the softener is injected into the de-electrifying roller 53, the softener soaks the sponge sleeve 55 through a plurality of blanking holes, the softener is coated on the explosion-proof film through the sponge sleeve 55 to remove the static electricity on the explosion-proof film, then the explosion-proof film moves to the dryer 52, the softener on the explosion-proof film is dried through the dryer 52, then the explosion-proof film moves to the flattening roller 54, the anti-explosion film is wiped through the cotton cloth sleeve 56 on the flattening roller 54, softener is prevented from being remained on the anti-explosion film, meanwhile, the anti-explosion film can be flattened through the flattening roller 54 and the arrangement of the de-electrifying roller 53 and the bearing platform 51, the anti-explosion film is moved to the position of the rotating barrel frame 33 to be rolled, after the rolling is completed, the taking and placing plate 41 is opened, the sliding handle 35 is slid, the distance between the rotating barrel frame 33 and the sliding arc plate 34 is enlarged, the anti-explosion film is clamped in a loosening mode, the anti-explosion film roll is pushed along the direction of the groove formed in the rotating barrel frame 33, and therefore the anti-explosion film roll can be easily taken down from the rotating barrel frame 33 through the groove.

The above description is only an example of the present application and is not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (6)

1. The utility model provides an rupture membrane production coiling mechanism convenient to get material which characterized in that: including base (1), hold-in range (2), rolling subassembly (3), get and put subassembly (4) and go electric subassembly (5), base (1) is concave type structure setting, rolling subassembly (3) are the interval with going electric subassembly (5) and set up in base (1), and rolling subassembly (3) and go electric subassembly (5) and all run through the inner wall of base (1) and outwards extend, hold-in range (2) are located the side of base (1), and hold-in range (2) cover is established on rolling subassembly (3) and go electric subassembly (5), get and put subassembly (4) and slide to set up on the lateral wall of base (1), and get and put subassembly (4) and peg graft mutually with rolling subassembly (3).

2. The explosion-proof membrane production winding device convenient for material taking as claimed in claim 1, is characterized in that: the winding assembly (3) comprises an L-shaped seat (31), a winding motor (32), a rotating barrel frame (33), a sliding arc plate (34), a sliding handle (35) and a plurality of telescopic springs (36), wherein the rotating barrel frame (33) is horizontally positioned between the base (1) and the taking and placing assembly (4), one end of the rotating barrel frame (33) penetrates through the base (1) and extends outwards, the other end of the rotating barrel frame (33) is inserted into the taking and placing assembly (4), the L-shaped seat (31) is arranged on the side wall of the base (1), the winding motor (32) is arranged on the side wall of the L-shaped seat (31), the output end of the winding motor (32) penetrates through the L-shaped seat (31) and is connected with the rotating barrel frame (33), the sliding arc plate (34) is arranged in the rotating barrel frame (33) in a sliding manner, L-shaped arc grooves for sliding the two ends of the sliding arc plate (34) are formed in two inner walls of the rotating barrel frame (33), the utility model discloses a set up explosion-proof membrane, including slip barrel holder (33), slip handle (35) and slip arc board (34), every slip handle (35) are located the other end that rotates barrel holder (33), and slip handle (35) run through and rotate barrel holder (33) and are connected with slip arc board (34), every expanding spring (36) are equidistant setting on the lateral wall of slip arc board (34), and every expanding spring (36) all are connected with the inner wall that rotates barrel holder (33), be equipped with the fixed clearance of confession explosion-proof membrane between another lateral wall of slip arc board (34) and rotation barrel holder (33), set up the fluting that supplies the explosion-proof membrane to take out on the outer wall of rotation barrel holder (33).

3. The explosion-proof membrane production winding device convenient for material taking as claimed in claim 2, is characterized in that: the taking and placing assembly (4) comprises a taking and placing plate (41), a T-shaped sliding block (42), an L-shaped frame (43), an inserting block (44), a transverse plate (45), a connecting block (46), a stepping frame (47) and two compression springs (48), wherein an air hole is formed in the side wall of the base (1), the taking and placing plate (41) is vertically positioned at the air hole, the T-shaped sliding block (42) is arranged on the side wall of the taking and placing plate (41), a T-shaped groove for the T-shaped sliding block (42) to slide is formed in the side wall of the base (1), the T-shaped sliding block (42) is positioned in the T-shaped groove, the L-shaped frame (43) is arranged at the bottom of the base (1), the L-shaped frame (43) is positioned below the taking and placing plate (41), the inserting block (44) is inserted at the bottom of the taking and placing plate (41), the transverse plate (45) is arranged at the bottom of the inserting block (44), and the two compression springs (48) are arranged at the bottom of the transverse plate (45) at intervals, and the bottom of each compression spring (48) is connected with the L-shaped frame (43), the connecting block (46) is arranged at the bottom of the transverse plate (45), the connecting block (46) is positioned between the two compression springs (48), the bottom of the connecting block (46) penetrates through the L-shaped frame (43) and extends downwards, the stepping frame (47) is arranged at the bottom of the connecting block (46), and the rotary barrel frame (33) is spliced with the taking and placing plate (41).

4. The explosion-proof membrane production winding device convenient for material taking as claimed in claim 2, is characterized in that: the electricity removing component (5) comprises a bearing platform (51), a dryer (52), an electricity removing roller (53) and a flattening roller (54), the bearing platform (51) is arranged on the inner bottom wall of the base (1), the dryer (52) is arranged at the top of the base (1), the dryer (52) is positioned right above the bearing platform (51), the electricity removing roller (53) and the flattening roller (54) are horizontally spaced and positioned in the base (1), one ends of the electricity removing roller (53) and the flattening roller (54) are respectively and rotatably connected with the inner wall of one side of the base (1), the other ends of the electricity removing roller (53) and the flattening roller (54) respectively penetrate through the inner wall of the other side of the base (1) and extend outwards, the electricity removing roller (53) and the flattening roller (54) are respectively positioned at two sides of the dryer (52), the synchronous belt (2) is sleeved on the output ends of the electricity removing roller (53), the flattening roller (54) and the rolling motor (32), the inside of going electricity roller (53) is seted up the cavity, set up the blanking hole that a plurality of equidistant settings on the outer wall of going electricity roller (53), sponge cover (55) are established to the cover on the outer wall of going electricity roller (53), the cover is equipped with cotton cover (56) on the outer wall of flattening roller (54).

5. The explosion-proof membrane production winding device convenient for material taking as claimed in claim 3, is characterized in that: the outer wall of the taking and placing plate (41) is provided with a handle (49).

6. The explosion-proof membrane production winding device convenient for material taking as claimed in claim 4, is characterized in that: an injection port is formed in the outer wall of the de-electrifying roller (53), a plug (57) is inserted into the outer wall of the de-electrifying roller (53), and the plug (57) is positioned in the injection port.

Images