CN219429295U - Equipment is tailor to glass fiber net cloth pay-off bundle strip of rectifying - Google Patents

Abstract

The utility model discloses glass fiber mesh cloth feeding, correcting and bundling strip cutting equipment which comprises a feeding device, a cloth arranging and correcting device, a layer combining device, a traction device, a bundling strip device and a cutting device which are sequentially arranged along a production line. The glass fiber mesh cloth feeding, correcting and bundling strip cutting equipment adopting the structure realizes the processing of a production line and improves the production efficiency by arranging the processing device in a centralized way along the production line.

Description

Equipment is tailor to glass fiber net cloth pay-off bundle strip of rectifying

Technical Field

The utility model relates to the technical field of filter screen processing, in particular to glass fiber mesh cloth feeding, deviation rectifying and bundling strip cutting equipment.

Background

The glass fiber mesh cloth takes glass fiber woven fabric as a base material and is coated by high polymer anti-emulsion soaking. Therefore, the composite material has good alkali resistance, flexibility and high tensile resistance in the warp and weft directions, and can be widely used for heat preservation, water resistance, fire resistance, crack resistance and the like of inner and outer walls of buildings. The glass fiber mesh cloth is mainly made of alkali-resistant glass fiber mesh cloth, and is formed by twisting medium alkali-free glass fiber yarns (mainly comprising silicate and having good chemical stability) through a special tissue structure, namely a leno tissue, and then performing high-temperature heat setting treatment such as alkali resistance, reinforcing agent and the like.

The existing glass fiber mesh cloth can be used as a filter screen, when the glass fiber mesh cloth is used as the filter screen, the mesh cloth is cut into large pieces through hydraulic scissors, then the large pieces are manually cut into strips, the strips are wrapped by plastic packaging films through a heat-sealing machine, and finally the large pieces are cut into a piece type filter, so that the problems of complicated process procedures, low efficiency, high labor cost and the like exist.

Disclosure of Invention

In order to solve the problems, the utility model provides the glass fiber mesh cloth feeding, correcting and bundling strip cutting equipment, which realizes the processing of a production line and improves the production efficiency by arranging the processing devices in a centralized way along the production line.

In order to achieve the aim, the utility model provides glass fiber mesh cloth feeding, correcting and bundling strip cutting equipment, which comprises a feeding device, a cloth arranging and guiding device, a laminating device, a traction device, a bundling strip device and a cutting device which are sequentially arranged along a production line.

Preferably, the feeding device is of a double-side feeding structure;

the feeding device comprises a feeding frame and feeding support frames fixed at two ends of the feeding frame, the feeding frame comprises a plurality of horizontal bearing rods which are arranged in parallel, feeding components are arranged on two sides of each horizontal bearing rod, each feeding component comprises a plurality of feeding shafts which are horizontally and linearly and uniformly arranged on the horizontal bearing rods in a rotating mode, and each feeding shaft is inserted with a material shaft;

a plurality of groups of feeding combination layer assemblies are arranged on the feeding support frame close to the cloth arranging and guiding device, each feeding combination layer assembly comprises two feeding combination layer shafts which are rotatably arranged on the feeding frame and are arranged in parallel up and down, and each feeding combination layer shaft is arranged in parallel with each feeding shaft;

the material roll is led out from the feeding shaft and then penetrates between the two feeding laminating shafts.

Preferably, the cloth arranging and guiding device comprises a cloth arranging support frame, a cloth arranging mechanism and a guiding mechanism;

the cloth arranging mechanism comprises a left-end cloth arranging component and a right-end cloth arranging component which are respectively arranged at two ends of the cloth arranging support frame;

the guide mechanism comprises a first guide component and a second guide component which are arranged in parallel between the left-end cloth arranging component and the right-end cloth arranging component;

the material rolls led out by the feeding device sequentially pass through the left-end cloth arranging component, the first guide component, the second guide component and the right-end cloth arranging component.

Preferably, the left end cloth arranging assembly and the right end cloth arranging assembly comprise a plurality of cloth arranging shafts which are arranged on the cloth arranging support frame in a vertical array in parallel in a rotating manner, and the material roll penetrates out from between two adjacent cloth arranging shafts;

the first guide assembly and the second guide assembly comprise a plurality of guide shafts which are arranged in the middle of the cloth arranging support frame in a vertical array in a rotating mode, and a material roll penetrates out from between two adjacent guide shafts;

the cloth arranging shaft and the guide shaft are parallel to the material shaft.

Preferably, a first deviation correcting mechanism is slidably arranged at the position of the cloth supporting frame corresponding to the correcting mechanism, the first deviation correcting mechanism comprises guide plates horizontally slidably arranged on the cloth supporting frame corresponding to the two ends of the correcting shaft, and the guide plates are vertically arranged with the correcting shaft;

the material rolls penetrate between the guide plates at the two ends.

Preferably, the layer combining device comprises a layer combining support frame, a first layer combining mechanism arranged at one end of the layer combining support frame facing the cloth guide device, and a second layer combining mechanism arranged at one end of the layer combining support frame away from the cloth guide device;

the first layer combining mechanism comprises a plurality of layer combining components, the layer combining components comprise two first layer combining shafts which are arranged on the layer combining support frame in an up-down parallel rotating mode, the number of the material shafts is an integral multiple of the number of the layer combining components, and the material shafts are used for rolling single-layer materials into a multi-layer material roll;

the second laminating mechanism comprises two second laminating shafts which are arranged on the laminating support frame in an up-down parallel rotation mode and used for rolling a plurality of groups of multi-layer materials led out by the multi-combination layer assembly into a group of material rolls.

Preferably, the traction device comprises a traction support frame, a horizontal moving mechanism arranged on the traction support frame, a vertical moving mechanism arranged at the output end of the horizontal moving mechanism and a lower pressing plate arranged at the output end of the vertical moving mechanism;

the horizontal moving mechanism comprises horizontal driving cylinders arranged on two sides of the traction support frame and a sliding block connected with the output end of the horizontal driving cylinders, the sliding block is horizontally and slidably connected with the traction support frame through a guide rod, and the guide rod is vertically arranged with the second laminating shaft;

the vertical moving mechanism comprises a vertical driving cylinder connected with the sliding block, and the vertical driving cylinder is connected with the lower pressing plate;

the material roll passes through the lower pressing plate.

Preferably, the strapping device comprises a strapping support frame, a feeding mechanism, a centering mechanism and a strapping mechanism which are sequentially arranged on the strapping support frame;

the feeding mechanism comprises two feeding shafts which are arranged in parallel up and down;

the centering mechanism comprises a centering plate group which is arranged on the strapping support frame in a sliding manner along the direction parallel to the feeding shaft, the centering plate group comprises two symmetrically arranged centering plates, and the centering plates are in positioning connection with the strapping support frame through positioning screws;

the bundling mechanism is a winding structure arranged around the material roll;

the material rolls sequentially pass through the space between the two feeding shafts, the space between the two centering plates and the bundling mechanism.

Preferably, the second deviation rectifying mechanisms are arranged on the feeding support frame and correspond to the two ends of the feeding layer combining shaft, the traction support frame and correspond to the two ends of the first layer combining shaft and the traction support frame and correspond to the two ends of the second layer combining shaft, each second deviation rectifying mechanism comprises two groups of deviation rectifying units which are oppositely arranged, each deviation rectifying unit comprises a stop lever and a positioning plate, one end of each positioning plate is fixed at the upper end and the lower end of each stop lever, and the other end of each positioning plate is in rotary connection with the feeding support frame or the traction support frame;

the stop lever is respectively and vertically arranged with the feeding laminating shaft, the first laminating shaft and the second laminating shaft.

Preferably, the cutting device is a punching cutting structure.

Compared with the prior art, the utility model has the following beneficial effects:

1. the glass fiber mesh cloth feeding, correcting and bundling strip cutting equipment realizes production line processing by arranging the processing device in a centralized way along the production line, and improves the production efficiency.

2. By arranging the material shafts on both sides of the feeding support frame, the placing space of the material rolls is increased, so that the number of feeding layers can be conveniently adjusted according to different processing requirements;

3. through setting up the reason cloth guide device that comprises many rollers, be convenient for adjust the synthetic layer number, processing is more nimble.

The technical scheme of the utility model is further described in detail through the drawings and the embodiments.

Drawings

FIG. 1 is a perspective view of the present utility model;

FIG. 2 is a schematic diagram of a feeding device according to the present utility model;

FIG. 3 is a schematic view of a fabric straightening device according to the present utility model;

FIG. 4 is a schematic diagram of a lamination device according to the present utility model;

FIG. 5 is a schematic diagram of a traction device according to the present utility model;

FIG. 6 is a schematic view of the strapping apparatus of the present utility model;

fig. 7 is a schematic process diagram of the present utility model.

Wherein: 1. a feeding device; 11. a horizontal carrier bar; 12. a feeding support frame; 13. a feeding shaft; 14. feeding a lamination shaft;

2. a cloth straightening device; 21. a cloth supporting frame; 22. a cloth arranging mechanism; 221. a left end cloth arranging component; 222. a right-end cloth arranging component; 23. a guide mechanism; 231. a first guide assembly; 232. a second guide assembly;

3. a lamination device; 31. a laminated support frame; 32. a first lamination mechanism; 33. a second lamination mechanism;

4. a traction device; 41. traction support frame; 42. a horizontal movement mechanism; 43. a vertical movement mechanism; 44. a lower pressing plate;

5. a strapping device; 51. a feed mechanism; 52. a centering mechanism; 53. a strapping bar support frame; 54. a strapping mechanism;

6. a second deviation correcting mechanism; 61. a stop lever; 62. and (5) positioning the plate.

Detailed Description

The present utility model will be further described with reference to the accompanying drawings, and it should be noted that, while the present embodiment provides a detailed implementation and a specific operation process on the premise of the present technical solution, the protection scope of the present utility model is not limited to the present embodiment.

The structure of the utility model comprises a feeding device 1, a cloth straightening device 2, a layer combining device 3, a traction device 4, a bundling device 5 and a cutting device which are sequentially arranged along a production line.

Specifically, the feeding device 1 is of a double-side feeding structure; the feeding device 1 comprises a feeding frame and feeding support frames 12 fixed at two ends of the feeding frame, wherein the feeding frame comprises a plurality of horizontal bearing rods 11 which are arranged in parallel, feeding components are arranged on two sides of each horizontal bearing rod 11, each feeding component comprises a plurality of feeding shafts 13 which are horizontally and linearly and uniformly arranged on the horizontal bearing rods 11 in a rotating mode, each feeding shaft 13 is inserted with a material shaft, and the material shafts are in interference fit with a material roll; a plurality of groups of feeding combination layer assemblies are arranged on the feeding support frame 12 close to the cloth arranging and guiding device 2, each feeding combination layer assembly comprises two feeding combination layer shafts 14 which are rotatably arranged on the feeding frame and are arranged in parallel up and down, and each feeding combination layer shaft 14 is arranged in parallel with each feeding shaft 13; the material rolls are led out from the feeding shafts 13 and then penetrate between the two feeding laminating shafts 14, the material shafts with the material rolls can be selectively placed on different feeding shafts 13 in the embodiment, then the ends of the material rolls are pulled, every n layers of the material rolls pass through the two feeding laminating shafts 14, a plurality of layers of material rolls are laminated, 50 groups of material shafts are arranged on the feeding support frame 12 in the embodiment, and every 10 groups of material rolls pass through a group of feeding laminating assemblies, so that 5 groups of multi-layer material rolls are formed, every 10 layers of material rolls pass through the cloth arranging and guiding device 2, the laminating device 3 and the traction device 4 in sequence.

Preferably, the cloth alignment device 2 comprises a cloth support frame 21, a cloth alignment mechanism 22 and an alignment mechanism 23; wherein, the cloth arranging mechanism 22 comprises a left end cloth arranging component 221 and a right end cloth arranging component 222 which are respectively arranged at two ends of the cloth arranging support frame 21; the guide mechanism 23 includes a first guide member 231 and a second guide member 232 disposed in parallel between the left-end cloth assembly 221 and the right-end cloth assembly 222; the roll led out by the feeding device 1 passes through the left-end feeding cloth treating assembly 221, the first guiding assembly 231, the second guiding assembly 232 and the right-end feeding cloth treating assembly 222 in sequence.

More specifically, the left end cloth arranging assembly 221 and the right end cloth arranging assembly 222 each include a plurality of cloth arranging shafts arranged on the cloth arranging support frame 21 in a vertical array in parallel and rotated, and the material roll passes through between two adjacent cloth arranging shafts; the first guide assembly 231 and the second guide assembly 232 comprise a plurality of guide shafts which are arranged in the middle of the cloth supporting frame 21 in a vertical array in a rotating way, and the material roll passes through the space between two adjacent guide shafts; the cloth arranging shaft and the guide shaft are parallel to the material shaft;

preferably, the first deviation correcting mechanism is slidably arranged at the position of the cloth supporting frame 21 corresponding to the correcting mechanism 23, the first deviation correcting mechanism comprises guide plates horizontally slidably arranged on the cloth supporting frame 21 corresponding to the two ends of the correcting shaft, and the guide plates are vertically arranged with the correcting shaft;

the material roll penetrates between the guide plates at the two ends.

In this embodiment, 5 groups of 10-layer rolls led out by the feeding device 1 are penetrated into the left-end fabric arranging component 221 of the fabric arranging and guiding device 2, and two adjacent layers of rolls are separated by a fabric arranging shaft, so that 50 single-layer rolls are formed, and then the 50 single-layer rolls respectively pass through the first guiding component 231 between the two corresponding guide plates, the second guiding component 232 between the two guide plates and the right-end fabric arranging component 222, so that layered deviation correction is realized.

Preferably, the layer combining device 3 comprises a layer combining support frame 31, a first layer combining mechanism 32 arranged at one end of the layer combining support frame 31 facing the cloth guide device 2, and a second layer combining mechanism 33 arranged at one end of the layer combining support frame 31 away from the cloth guide device 2; the first lamination mechanism 32 comprises a plurality of lamination assemblies, the lamination assemblies comprise two first lamination shafts which are arranged on the lamination support frame 31 in a vertically parallel rotating manner, the number of the first lamination shafts is an integral multiple of the number of the lamination assemblies, the first lamination shafts are used for rolling single-layer materials into a plurality of layers of material rolls, in the embodiment, the lamination assemblies are used for rolling the single-layer materials into 10 layers of material rolls again;

the second lamination mechanism 33 includes two second lamination shafts that are rotatably disposed on the lamination support frame 31 in parallel up and down, and is used for rolling up a plurality of groups of multi-layer materials led out by the multi-lamination assembly into a group of material rolls, and rolling up 10 layers of materials into 50 layers of material rolls in this embodiment.

Preferably, the traction device comprises a traction support frame 41, a horizontal moving mechanism 42 arranged on the traction support frame 41, a vertical moving mechanism 43 arranged at the output end of the horizontal moving mechanism 42 and a lower pressing plate 44 arranged at the output end of the vertical moving mechanism 43; the horizontal moving mechanism 42 comprises horizontal driving cylinders arranged on two sides of the traction support frame 41 and a sliding block connected with the output end of the horizontal driving cylinders, the sliding block is horizontally and slidably connected with the traction support frame 41 through a guide rod, and the guide rod is vertically arranged with the second lamination shaft; the vertical moving mechanism 43 comprises a vertical driving cylinder connected with the sliding block, and the vertical driving cylinder is connected with the lower pressing plate 44; the material rolls up by holding down plate 44 and wears out, in this embodiment, when pulling, at first the horizontal drive cylinder drives the vertical movement cylinder and moves to the direction that is close to closing layer device 3, and after the back that targets in place, the vertical drive cylinder drives holding down plate 44 and moves down, can draw the play material roll with the help of the frictional force between holding down plate 44 and the material roll, and then the horizontal drive cylinder drives the vertical movement cylinder and resets, can draw the play material roll again to realize the traction function.

Preferably, the strapping device 5 includes a strapping support frame 53, and a feeding mechanism 51, a centering mechanism 52, and a strapping mechanism 54 sequentially disposed on the strapping support frame 53; wherein the feeding mechanism 51 comprises two feeding shafts which are arranged in parallel up and down; the centering mechanism 52 comprises a centering plate group which is arranged on the strapping support 53 in a sliding manner along the direction parallel to the feeding shaft, the centering plate group comprises two centering plates which are symmetrically arranged, and the centering plates are in positioning connection with the strapping support 53 through positioning screws; the strapping mechanism 54 is a winding structure disposed around the coil, and it should be noted that the structural principle of the strapping mechanism 54 is common in the art, so that no description is given here; the rolls pass in turn between the two feed shafts, between the two centering plates and the strapping mechanism 54.

In this embodiment the log guided out by the traction device 4 is first fed between the two feed shafts, then passes between the two centring plates, centring is achieved, finally enters the strapping mechanism 54, and spirals the strapping as it advances over the log surface.

Preferably, the second deviation correcting mechanisms 6 are arranged on the feeding support frame 12 and correspond to the two ends of the feeding layer combining shaft 14, the traction support frame 41 and correspond to the two ends of the first layer combining shaft and the traction support frame 41 and correspond to the two ends of the second layer combining shaft, each second deviation correcting mechanism 6 comprises two groups of deviation correcting units which are oppositely arranged, each deviation correcting unit comprises a stop lever 61 and a positioning plate 62, one end of each positioning plate 62 is fixed on the upper end and the lower end of each stop lever 61, and the other end of each positioning plate 62 is in rotary connection with the feeding support frame 12 or the traction support frame 41; the bars 61 are arranged perpendicular to the feed lamination axis 14, the first lamination axis and the second lamination axis, respectively. When the device is used, the stop rods 61 are rotated at first, the positions between the two stop rods 61 are adjusted until the positions are parallel to the feeding direction of the coil, and then the coil passes through the positioning plate 62 to the feeding support frame 12 or the traction support frame 41 by means of screws, so that deviation correction is realized.

Preferably, the cutting device is a punching cutting structure, and the structural principle of the punching cutting structure is common knowledge in the art, so that the description is omitted here.

Therefore, the glass fiber mesh cloth feeding, correcting and bundling strip cutting equipment adopting the structure realizes the processing of a production line and improves the production efficiency by arranging the processing devices in a centralized way along the production line.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present utility model and not for limiting it, and although the present utility model has been described in detail with reference to the preferred embodiments, it will be understood by those skilled in the art that: the technical scheme of the utility model can be modified or replaced by the same, and the modified technical scheme cannot deviate from the spirit and scope of the technical scheme of the utility model.

Claims (10)

1. The utility model provides a glass fiber net cloth pay-off correction bundle strip tailors equipment which characterized in that: comprises a feeding device, a cloth arranging and guiding device, a laminating device, a traction device, a bundling device and a cutting device which are sequentially arranged along a production line.

2. The glass fiber mesh cloth feeding deviation rectifying bundle strip cutting device according to claim 1, wherein: the feeding device is of a double-side feeding structure;

the feeding device comprises a feeding frame and feeding support frames fixed at two ends of the feeding frame, the feeding frame comprises a plurality of horizontal bearing rods which are arranged in parallel, feeding components are arranged on two sides of each horizontal bearing rod, each feeding component comprises a plurality of feeding shafts which are horizontally and linearly and uniformly arranged on the horizontal bearing rods in a rotating mode, and each feeding shaft is inserted with a material shaft;

a plurality of groups of feeding combination layer assemblies are arranged on the feeding support frame close to the cloth arranging and guiding device, each feeding combination layer assembly comprises two feeding combination layer shafts which are rotatably arranged on the feeding frame and are arranged in parallel up and down, and each feeding combination layer shaft is arranged in parallel with each feeding shaft;

the material roll is led out from the feeding shaft and then penetrates between the two feeding laminating shafts.

3. The glass fiber mesh cloth feeding deviation rectifying bundle strip cutting device according to claim 2, wherein: the cloth arranging and guiding device comprises a cloth arranging support frame, a cloth arranging mechanism and a guiding mechanism;

the cloth arranging mechanism comprises a left-end cloth arranging component and a right-end cloth arranging component which are respectively arranged at two ends of the cloth arranging support frame;

the guide mechanism comprises a first guide component and a second guide component which are arranged in parallel between the left-end cloth arranging component and the right-end cloth arranging component;

the material rolls led out by the feeding device sequentially pass through the left-end cloth arranging component, the first guide component, the second guide component and the right-end cloth arranging component.

4. A glass fiber mesh cloth feeding deviation rectifying binding strip cutting device according to claim 3, characterized in that: the left-end cloth arranging assembly and the right-end cloth arranging assembly comprise a plurality of cloth arranging shafts which are arranged on the cloth arranging support frame in a vertical array in parallel in a rotating mode, and a material roll penetrates out from between two adjacent cloth arranging shafts;

the first guide assembly and the second guide assembly comprise a plurality of guide shafts which are arranged in the middle of the cloth arranging support frame in a vertical array in a rotating mode, and a material roll penetrates out from between two adjacent guide shafts;

the cloth arranging shaft and the guide shaft are parallel to the material shaft.

5. The glass fiber mesh cloth feeding and deviation rectifying bundle strip cutting device according to claim 4, wherein: the first deviation correcting mechanism is arranged at the position of the cloth supporting frame corresponding to the correcting mechanism in a sliding manner, the first deviation correcting mechanism comprises guide plates which are horizontally arranged on the cloth supporting frame in a sliding manner corresponding to the two ends of the correcting shaft, and the guide plates are arranged vertically to the correcting shaft;

the material rolls penetrate between the guide plates at the two ends.

6. The glass fiber mesh cloth feeding and deviation rectifying bundle strip cutting device according to claim 5, wherein: the layer combining device comprises a layer combining support frame, a first layer combining mechanism arranged at one end of the layer combining support frame facing the cloth guide device, and a second layer combining mechanism arranged at one end of the layer combining support frame away from the cloth guide device;

the first layer combining mechanism comprises a plurality of layer combining components, the layer combining components comprise two first layer combining shafts which are arranged on the layer combining support frame in an up-down parallel rotating mode, the number of the material shafts is an integral multiple of the number of the layer combining components, and the material shafts are used for rolling single-layer materials into a multi-layer material roll;

the second laminating mechanism comprises two second laminating shafts which are arranged on the laminating support frame in an up-down parallel rotation mode and used for rolling a plurality of groups of multi-layer materials led out by the multi-combination layer assembly into a group of material rolls.

7. The fiberglass mesh feeding and deviation rectifying binding strip cutting device according to claim 6, wherein: the traction device comprises a traction support frame, a horizontal moving mechanism arranged on the traction support frame, a vertical moving mechanism arranged at the output end of the horizontal moving mechanism and a lower pressing plate arranged at the output end of the vertical moving mechanism;

the horizontal moving mechanism comprises horizontal driving cylinders arranged on two sides of the traction support frame and a sliding block connected with the output end of the horizontal driving cylinders, the sliding block is horizontally and slidably connected with the traction support frame through a guide rod, and the guide rod is vertically arranged with the second laminating shaft;

the vertical moving mechanism comprises a vertical driving cylinder connected with the sliding block, and the vertical driving cylinder is connected with the lower pressing plate;

the material roll passes through the lower pressing plate.

8. The fiberglass mesh feeding and deviation rectifying binding strip cutting device according to claim 7, wherein: the binding strip device comprises a binding strip supporting frame, a feeding mechanism, a centering mechanism and a binding strip mechanism which are sequentially arranged on the binding strip supporting frame;

the feeding mechanism comprises two feeding shafts which are arranged in parallel up and down;

the centering mechanism comprises a centering plate group which is arranged on the strapping support frame in a sliding manner along the direction parallel to the feeding shaft, the centering plate group comprises two symmetrically arranged centering plates, and the centering plates are in positioning connection with the strapping support frame through positioning screws;

the bundling mechanism is a winding structure arranged around the material roll;

the material rolls sequentially pass through the space between the two feeding shafts, the space between the two centering plates and the bundling mechanism.

9. The fiberglass mesh feeding and deviation rectifying binding strip cutting device according to claim 8, wherein: the feeding support frame is provided with a first deviation rectifying mechanism, the first deviation rectifying mechanism is arranged on the feeding support frame and corresponds to the two ends of the feeding layer combining shaft, the traction support frame is provided with a second deviation rectifying mechanism which comprises two groups of deviation rectifying units which are oppositely arranged, the deviation rectifying units comprise a stop lever and positioning plates, one ends of the positioning plates are fixed at the upper end and the lower end of the stop lever, and the other ends of the positioning plates are in rotary connection with the feeding support frame or the traction support frame;

the stop lever is respectively and vertically arranged with the feeding laminating shaft, the first laminating shaft and the second laminating shaft.

10. The fiberglass mesh feeding and deviation rectifying binding strip cutting device according to claim 8, wherein: the cutting device is of a punching cutting structure.