CN113428703A - Smooth winding device for glass fiber gridding cloth - Google Patents

Abstract

The invention relates to a flattening winding device, in particular to a glass fiber mesh fabric flattening winding device. The glass fiber mesh fabric flattening and winding device capable of flattening and quantitatively winding the mesh fabric to the thickness is provided. A glass fiber gridding cloth flattening and winding device comprises: the base is used for mounting the whole equipment; the leveling assembly is arranged on the base and levels in a sliding mode; the winding assembly is arranged on the leveling assembly and provides power for winding cloth; the pushing assembly is installed on the leveling assembly and pushed in a contact mode. According to the invention, the half-tooth gear is matched with the rack, the glass fiber mesh cloth can be pushed to be flat intermittently, the glass fiber mesh cloth can be wound rapidly through the matching of the speed reducing motor and the winding rod, the working efficiency is improved, and the wound glass fiber mesh cloth can be supported and limited through the matching of the special-shaped guide rail and the arc-shaped plate.

Description

Smooth winding device for glass fiber gridding cloth

Technical Field

The invention relates to a flattening winding device, in particular to a glass fiber mesh fabric flattening winding device.

Background

The glass fiber mesh fabric is prepared by taking glass fiber woven fabric as a base material and soaking a coating layer by using a high-molecular anti-emulsion. Therefore, the glass fiber mesh fabric has good alkali resistance, flexibility and high tensile resistance in the warp and weft directions, can be widely used for heat preservation, water resistance, fire resistance, crack resistance and the like of inner and outer walls of buildings, and after the glass fiber mesh fabric is manufactured, workers need to smoothly wind the glass fiber mesh fabric.

The patent with the patent publication number of CN205011124U discloses a glass fiber cloth glue mixing and coating winding machine, which comprises a glass fiber cloth glue mixing hiking winding machine frame, an automatic glue mixing component connected with the glass fiber cloth glue mixing hiking winding machine frame, a glass fiber cloth baking box arranged on the glass fiber cloth glue mixing hiking winding machine frame, and a glass fiber cloth deviation rectifying module; the invention relates to a glass fiber cloth mixed glue walking winder, which is characterized in that a glass fiber cloth winding module, a glue scraping plate module, a glass fiber cloth pressing module, a glass fiber cloth tension detection module, a glass fiber cloth supporting module and a glass fiber cloth feeding module are arranged in a rack of the glass fiber cloth mixed glue walking winder.

Therefore, a glass fiber mesh fabric flattening and winding device capable of flattening and quantitatively winding the mesh fabric with the thickness is needed to be developed.

Disclosure of Invention

In order to overcome the current mode of coiling to the net cloth can not be with the net cloth of fold levelly and smoothly, can not be quantitative coil the net cloth to certain thickness and stop the shortcoming, the technical problem: the glass fiber mesh fabric flattening and winding device capable of flattening and quantitatively winding the mesh fabric to the thickness is provided.

The technical scheme is as follows: a glass fiber gridding cloth flattening and winding device comprises: the base is used for mounting the whole equipment; the leveling assembly is arranged on the base and levels in a sliding mode; the winding assembly is arranged on the leveling assembly and provides power for winding cloth; the pushing assembly is installed on the leveling assembly and pushed in a contact mode.

Preferably, the leveling assembly comprises: the placing plate is arranged on the base; the two movable plates are arranged and are arranged on the placing plate in a sliding mode; the pushing plate is arranged between the moving plates in a sliding manner and is matched with the placing plate; the first spring is connected between the pushing plate and the moving plate; the special-shaped rod is slidably mounted on the placing plate; the second spring is connected between the special-shaped rod and the placing plate; and the rack is arranged on the special-shaped rod.

Preferably, the winding assembly comprises: the speed reducing motor is arranged on the placing plate; the half-tooth gear is arranged on an output shaft of the speed reducing motor and matched with the rack; the fixed rod is arranged on the placing plate; the belt pulley set is arranged between the fixed rod and the output shaft of the speed reducing motor; and the winding rod is arranged on the fixed rod and penetrates through the fixed rod to be connected with the belt pulley group.

Preferably, the pushing assembly comprises: the circular sliding sleeve is arranged on the placing plate; the first wedge-shaped block is slidably arranged in the circular sliding sleeve; and the third spring is connected between the first wedge-shaped block and the circular sliding sleeve, and the push plate is matched with the first wedge-shaped block.

Preferably, the method further comprises the following steps: spacing subassembly, spacing subassembly is including: the two special-shaped guide rails are arranged on the placing plate; the sliding block is arranged in the special-shaped guide rail in a sliding manner; the fourth spring is connected between the sliding block and the special-shaped guide rail; the arc-shaped plate is arranged on the sliding block in a sliding manner; and the pressure spring is connected between the arc-shaped plate and the sliding block.

Preferably, the mobile device further comprises a moving assembly, wherein the moving assembly comprises: the square sliding sleeve is arranged on the placing plate; the moving rod is slidably arranged in the square sliding sleeve; the fifth spring is connected between the moving rod and the square sliding sleeve; the second wedge-shaped block is arranged on the moving rod, and the arc-shaped plate is matched with the second wedge-shaped block; the third wedge block is arranged on the movable rod; the baffle is arranged on the placing plate in a sliding mode and matched with the winding rod; the telescopic rod is arranged on the baffle in a sliding manner and is matched with the placing plate; and the sixth spring is connected between the baffle plate and the placing plate and is in a stretching state.

Preferably, still include and stir the subassembly, stir the subassembly including: the mounting rack is mounted on the placing plate; the rotating rod is rotatably arranged between the mounting frame and the placing plate; and the swing rod is arranged on the rotating rod, and the rotating rod is connected with an output shaft of the speed reducing motor.

Preferably, the method further comprises the following steps: the telescopic link, the tip of telescopic link just can block with placing the board.

The invention has the beneficial effects that: according to the invention, the glass fiber gridding cloth can be pushed to be flat intermittently by matching the semi-tooth gear with the rack, the glass fiber gridding cloth can be wound quickly by matching the speed reducing motor with the winding rod, the working efficiency is improved, the wound glass fiber gridding cloth can be supported and limited by matching the special-shaped guide rail with the arc-shaped plate, the glass fiber gridding cloth can be loosened when the glass fiber gridding cloth is wound to a certain thickness by matching the third wedge-shaped block with the telescopic rod, and the glass fiber gridding cloth can be shifted to the right by matching the rotating rod with the oscillating rod, so that the winding of the glass fiber gridding cloth is straighter and flatter.

Drawings

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

FIG. 2 is a schematic view of a first partial body structure according to the present invention.

FIG. 3 is a schematic view of a second partial body structure according to the present invention.

Fig. 4 is a perspective view of a third embodiment of the present invention.

Fig. 5 is a perspective view of a fourth embodiment of the present invention.

FIG. 6 is a schematic view of a fifth partial body structure according to the present invention.

Description of reference numerals: 1_ base, 2_ leveling component, 21_ placing plate, 22_ moving plate, 23_ pushing flat plate, 24_ first spring, 25_ shaped rod, 26_ second spring, 27_ rack, 3_ winding component, 31_ speed reducing motor, 32_ half-tooth gear, 33_ fixed rod, 34_ pulley group, 35_ winding rod, 4_ pushing component, 41_ circular sliding sleeve, 42_ first wedge block, 43_ third spring, 5_ limiting component, 51_ profile rail, 52_ sliding block, 53_ fourth spring, 54_ arc plate, 55_ pressure spring, 6_ moving component, 61_ square sliding sleeve, 62_ moving rod, 63_ fifth spring, 64_ second wedge block, 65_ third wedge block, 66_ baffle, 67_ telescopic rod, 68_ sixth spring, 7_ toggle component, 71_ mounting block, 72_ rotating rod, 73_ rocking rod.

Detailed Description

The invention is further described with reference to the following figures and detailed description.

Example 1

The utility model provides a glass fiber net check cloth evens coiling mechanism, as shown in fig. 1-3, including base 1, level and smooth subassembly 2, winding assembly 3 and promotion subassembly 4, base 1 is used for installing whole equipment, and base 1 top is equipped with and carries out leveled smooth subassembly 2 through the slip mode, levels 2 rear side right parts of subassembly and is equipped with the winding assembly 3 that provides power and carry out the batching, levels 2 front side left parts of subassembly and is equipped with the promotion subassembly 4 that promotes through the contact mode.

When needs were levelly and smoothly convoluteed glass fiber net check cloth, the staff twined winding assembly 3 with the one end of glass fiber net check cloth earlier, then started winding assembly 3 and rotated, it smooths glass fiber net check cloth to drive leveling assembly 2, leveling assembly 2 carries out work with the cooperation of promotion subassembly 4 afterwards, when glass fiber net check cloth convoluteed certain thickness, the staff will convolute winding assembly 3 and close, then with the disconnection of glass fiber net check cloth, it can to take off the glass fiber net check cloth that will convolute afterwards from winding assembly 3.

As shown in fig. 1 and 2, the leveling assembly 2 includes a placing plate 21, a moving plate 22, two pushing plates 23, a first spring 24, a special-shaped rod 25, a second spring 26 and a rack 27, the placing plate 21 is fixedly connected to the top of the base 1 through bolts, the moving plates 22 are provided with two moving plates 22, the moving plate 22 is slidably arranged on the lower portion of the placing plate 21, the pushing plates 23 are slidably arranged between the moving plates 22, the pushing plates 23 are matched with the placing plate 21, the first springs 24 are connected between the pushing plates 23 and the moving plate 22, the special-shaped rod 25 is slidably arranged on the left portion of the rear side of the placing plate 21, the special-shaped rod 25 is connected with the moving plate 22, the second springs 26 are connected between the special-shaped rod 25 and the placing plate 21, and the rack 27 is fixedly connected to the other ends of the special-shaped rods 25 through screws.

When the winding assembly 3 works, the rack 27 is pushed to move rightwards, the special-shaped rod 25 is driven to slide rightwards, the second spring 26 is compressed, the moving plate 22 is driven to slide rightwards, the pushing plate 23 is driven to move rightwards, the pushing plate 23 is driven to slide upwards when the pushing plate 23 is in contact with the pushing assembly 4, the first spring 24 is compressed, when the pushing plate 23 is separated from the pushing assembly 4, the first spring 24 rebounds to drive the pushing plate 23 to move downwards, then the rack 27 is pushed to be not matched with the winding assembly 3, the special-shaped rod 25 and the upper device of the special-shaped rod 25 are driven to move leftwards under the action of the second spring 26 to reset so as to push the glass fiber gridding cloth to be leveled, and the glass fiber gridding cloth is leveled through repeated movement.

As shown in fig. 1 and 3, the winding assembly 3 includes a reduction motor 31, a half-gear 32, a fixing rod 33, a pulley set 34 and a winding rod 35, the reduction motor 31 is fixedly connected to the right portion of the rear side of the placing plate 21 through a bolt, the half-gear 32 is arranged on an output shaft of the reduction motor 31, the half-gear 32 is matched with the rack 27, the fixing rod 33 is fixedly connected to the right portion of the top of the placing plate 21 through a bolt, the pulley set 34 is wound between the rear side of the fixing rod 33 and the output shaft of the reduction motor 31, the winding rod 35 is rotatably arranged on the upper portion of the front side of the fixing rod 33, and the winding rod 35 penetrates through the fixing rod 33 and is connected with the pulley set 34.

When winding the fine net cloth of glass around winding rod 35 on, control gear motor 31 work, drive half tooth gear 32 and rotate, when tooth on half tooth gear 32 and rack 27 contact, promote rack 27 and remove right, and simultaneously, drive pulley block 34 and rotate, and then drive winding rod 35 and rotate and coil cloth, when coiling certain thickness to fine net cloth of glass, close gear motor 31, the fine net cloth of glass that will convolute is taken off from winding rod 35 afterwards, so, can be quick coil fine net cloth of glass, and the work efficiency is improved.

As shown in fig. 1 and 2, the pushing assembly 4 includes a circular sliding sleeve 41, a first wedge 42 and a third spring 43, the circular sliding sleeve 41 is fixedly connected to the front side of the top of the placing plate 21 through a screw, the first wedge 42 is slidably disposed in the circular sliding sleeve 41, the third spring 43 is connected between the first wedge 42 and the circular sliding sleeve 41, and the pushing plate 23 is engaged with the first wedge 42.

When the push flat plate 23 moves rightwards, the push flat plate 23 is in contact with the first wedge-shaped block 42, so that the push flat plate 23 moves upwards, when the push flat plate 23 is separated from the first wedge-shaped block 42, the push flat plate 23 moves downwards, when the push flat plate 23 moves leftwards and is in contact with the first wedge-shaped block 42, the first wedge-shaped block 42 is pushed to move upwards, the third spring 43 is compressed, and when the push flat plate 23 is separated from the first wedge-shaped block 42, the first wedge-shaped block 42 is driven to move downwards to reset under the action of the third spring 43.

Example 2

On the basis of embodiment 1, as shown in fig. 1 and 4, the positioning device further comprises a positioning assembly 5, the positioning assembly 5 comprises a special-shaped guide rail 51, two sliding blocks 52, four springs 53, an arc-shaped plate 54 and two pressure springs 55, the special-shaped guide rail 51 is fixedly connected to the right side of the top of the placing plate 21 through bolts, the sliding blocks 52 are arranged in the special-shaped guide rail 51 in a sliding manner, the fourth springs 53 are connected between the sliding blocks 52 and the special-shaped guide rail 51, the arc-shaped plates 54 are arranged on the sliding blocks 52 in a sliding manner, and the two pressure springs 55 are connected between the arc-shaped plates 54 and the sliding blocks 52.

When the glass fiber gridding cloth is thicker and thicker, the arc-shaped plate 54 is pushed to move rightwards, the sliding block 52 is driven to slide rightwards, the fourth spring 53 is compressed, meanwhile, the arc-shaped plate 54 slides downwards, the pressure spring 55 is compressed, when the glass fiber gridding cloth on the winding rod 35 is taken down, the sliding block 52 is driven to slide leftwards under the action of the fourth spring 53 to reset, meanwhile, the arc-shaped plate 54 is driven to move upwards under the action of the pressure spring 55 to reset, and therefore the wound glass fiber gridding cloth can be supported and limited.

On the basis of embodiment 1, as shown in fig. 1 and 5, the mobile assembly 6 further comprises a moving assembly 6, the moving assembly 6 comprises a square sliding sleeve 61, a moving rod 62, a fifth spring 63, a second wedge block 64, a third wedge block 65, a baffle 66, an expansion link 67 and a sixth spring 68, the square sliding sleeve 61 is fixedly connected to the right side of the top of the placing plate 21 through a bolt, the moving rod 62 is slidably arranged in the square sliding sleeve 61, the fifth spring 63 is connected between the moving rod 62 and the square sliding sleeve 61, the second wedge block 64 is fixedly connected to the rear of the moving rod 62 through a bolt, the arc plate 54 is matched with the second wedge block 64, the third wedge block 65 is fixedly connected to the front side of the moving rod 62 through a bolt, the baffle 66 is slidably arranged at the right part of the placing plate 21, the baffle 66 is matched with the third wedge block 65, the baffle 66 is matched with the winding rod 35, the expansion link 67 is slidably arranged at the left side of the baffle 66, the expansion link 67 is matched with the placing plate 21, a sixth spring 68 is connected between the shutter 66 and the placement plate 21, and the sixth spring 68 is in a stretched state.

When the arc plate 54 slides downwards, the second wedge block 64 is pushed to move forwards to drive the moving rod 62 to slide forwards, the fifth spring 63 is compressed to drive the second wedge block 64 to move forwards, when the third wedge block 65 is in contact with the telescopic rod 67, the telescopic rod 67 is pushed to move upwards, the baffle 66 is driven to slide rightwards to reset under the action of the sixth spring 68, the telescopic rod 67 is driven to move rightwards to reset, meanwhile, the baffle 66 is separated from the winding rod 35, when the glass fiber gridding cloth is taken down, the arc plate 54 is separated from the second wedge block 64, the moving rod 62 and the upper device thereof are driven to move backwards to reset under the action of the fifth spring 63, meanwhile, a worker pushes the baffle 66 to slide leftwards, the sixth spring 68 is stretched to drive the telescopic rod 67 to move leftwards, and is clamped on the placing plate 21 when the telescopic rod 67 moves to a proper position, so that when the glass fiber gridding cloth is wound to a certain thickness, and loosening the glass fiber mesh cloth.

On the basis of embodiment 1, as shown in fig. 1 and 6, the electric shock absorber further comprises a toggle assembly 7, the toggle assembly 7 comprises an installation frame 71, a rotating rod 72 and a swing rod 73, the installation frame 71 is fixedly connected to the right portion of the rear side of the placing plate 21 through a screw, the rotating rod 72 is rotatably arranged between the installation frame 71 and the placing plate 21, the swing rod 73 is welded on the rotating rod 72, and the rotating rod 72 is connected with an output shaft of the speed reducing motor 31.

When the output shaft of the speed reducing motor 31 rotates, the rotating rod 72 is driven to rotate, and then the oscillating rod 73 is driven to rotate, when the output shaft of the speed reducing motor 31 stops rotating, the rotating rod 72 and the device on the rotating rod stop rotating, so that the glass fiber meshes can be shifted to the right, and the glass fiber meshes are enabled to be wound more straightly and flatly.

The above-mentioned embodiments are merely preferred embodiments of the present invention, which are not intended to limit the scope of the present invention, and therefore, all equivalent changes made by the contents of the claims of the present invention should be included in the claims of the present invention.

Claims (8)

1. The utility model provides a smooth take-up device of glass fiber check cloth, characterized by, including:

the base (1) is used for installing the whole equipment;

the leveling component (2) is arranged on the base (1) and levels in a sliding mode;

the winding assembly (3) is arranged on the leveling assembly (2) and provides power for winding cloth;

the pushing assembly (4) is installed on the leveling assembly (2) and is pushed in a contact mode.

2. A glass web grid flat winding device according to claim 1, characterized in that the flattening assembly (2) comprises:

a placement plate (21) mounted on the base (1);

two moving plates (22), wherein the two moving plates (22) are arranged on the placing plate (21) in a sliding manner;

the pushing plate (23) is arranged between the moving plates (22) in a sliding manner, and the pushing plate (23) is matched with the placing plate (21);

a first spring (24) connected between the push plate (23) and the moving plate (22);

a special-shaped rod (25) which is slidably mounted on the placing plate (21);

a second spring (26) connected between the special-shaped rod (25) and the placing plate (21);

and a rack (27) mounted on the profile rod (25).

3. A glass web plait winding device according to claim 2, characterized in that the winding assembly (3) comprises: a reduction motor (31) mounted on the placement plate (21);

the half-tooth gear (32) is arranged on an output shaft of the speed reducing motor (31), and the half-tooth gear (32) is matched with the rack (27);

a fixing rod (33) mounted on the placing plate (21);

a pulley set (34) installed between the fixing rod (33) and the output shaft of the reduction motor (31);

and the winding rod (35) is arranged on the fixed rod (33), and the winding rod (35) penetrates through the fixed rod (33) to be connected with the belt pulley group (34).

4. A glass web plait winding apparatus according to claim 3, characterized in that the pushing assembly (4) comprises:

a circular sliding sleeve (41) mounted on the placing plate (21);

the first wedge-shaped block (42) is slidably arranged in the circular sliding sleeve (41);

and the third spring (43) is connected between the first wedge-shaped block (42) and the circular sliding sleeve (41), and the push plate (23) is matched with the first wedge-shaped block (42).

5. The flat winding apparatus for a glass fiber mesh fabric as claimed in claim 4, further comprising: spacing subassembly (5), spacing subassembly (5) including: two special-shaped guide rails (51), wherein the two special-shaped guide rails (51) are arranged on the placing plate (21);

a sliding block (52) which is slidably mounted in the special-shaped guide rail (51);

a fourth spring (53) connected between the slide block (52) and the shaped guide rail (51);

an arc plate (54) slidably mounted on the slide block (52);

and a pressure spring (55) connected between the arc plate (54) and the sliding block (52).

6. A flat winder for glass fiber webs according to claim 5, further comprising a moving assembly (6), the moving assembly (6) comprising: a square sliding sleeve (61) which is arranged on the placing plate (21);

the moving rod (62) is slidably arranged in the square sliding sleeve (61);

the fifth spring (63) is connected between the moving rod (62) and the square sliding sleeve (61);

the second wedge-shaped block (64) is arranged on the moving rod (62), and the arc-shaped plate (54) is matched with the second wedge-shaped block (64);

a third wedge (65) mounted on the travel bar (62);

the baffle (66) is arranged on the placing plate (21) in a sliding mode, and the baffle (66) is matched with the winding rod (35);

the telescopic rod (67) is arranged on the baffle (66) in a sliding manner, and the telescopic rod (67) is matched with the placing plate (21);

and a sixth spring (68) connected between the shutter (66) and the placement plate (21), wherein the sixth spring (68) is in a stretched state.

7. A flat winder for glass fiber webs according to claim 6, further comprising a toggle assembly (7), the toggle assembly (7) comprising:

a mounting frame (71) mounted on the placement plate (21);

a rotating rod (72) rotatably mounted between the mounting rack (71) and the placing plate (21);

the swing rod (73) is arranged on the rotating rod (72), and the rotating rod (72) is connected with an output shaft of the speed reducing motor (31).

8. The flat winding apparatus for a glass fiber mesh fabric as claimed in claim 6, further comprising:

the end part of the telescopic rod (67) and the placing plate (21) can be just clamped.

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