CN113459489A - Automatic chemical fiber winding machine - Google Patents

Abstract

The invention discloses an automatic fiber winding machine which comprises an automatic fiber winding machine and a fiber winding unit, wherein the automatic fiber winding machine comprises an automatic tensioning rotary unit and the fiber winding unit, the automatic tensioning rotary unit realizes the fixation and rotation of a glass fiber reinforced plastic sleeve, and the fiber winding unit realizes the fiber supply of glass fiber reinforced plastic. The device provided by the invention can be suitable for glass fiber reinforced plastic sleeves without diameters by automatically tensioning the rotating unit, the application range of the machine is greatly increased, the tensioning rod can be contracted and rotated only by arranging one driving device, fewer parts are used, and the cost is lower.

Description

Automatic chemical fiber winding machine

Technical Field

The invention relates to the technical field of winding machines, in particular to an automatic chemical fiber winding machine.

Background

The glass fiber reinforced plastic winding machine has the advantages and characteristics of high reaction speed, strong anti-interference capability, convenient use, convenient adjustment, flexible assembly and multiple purposes. The glass fiber reinforced plastic winding machine is deeply favored by the same people in the domestic glass fiber reinforced plastic industry.

Most of the existing glass fiber reinforced plastic fiber winding machines can only be suitable for glass fiber reinforced plastic sleeves with single diameter, and the application range is too small, so that the glass fiber reinforced plastic fiber winding machines are not beneficial to industrial development.

Disclosure of Invention

This section is for the purpose of summarizing some aspects of embodiments of the invention and to briefly introduce some preferred embodiments. In this section, as well as in the abstract and the title of the invention of this application, simplifications or omissions may be made to avoid obscuring the purpose of the section, the abstract and the title, and such simplifications or omissions are not intended to limit the scope of the invention.

The present invention has been made in view of the above and/or other problems with the prior art filament winding machines.

Therefore, the problem to be solved by the invention is how to solve the problem that the glass fiber reinforced plastic fiber winding machine can only be suitable for the glass fiber reinforced plastic sleeve with a single diameter.

In order to solve the technical problems, the invention provides the following technical scheme: an automatic fiber winding machine comprises an automatic tensioning rotary unit, a winding device and a winding device, wherein the automatic tensioning rotary unit comprises side plates which are symmetrically arranged, a base matched with the side plates and a tensioning rotary piece arranged in the side plates; the fiber winding unit is arranged corresponding to the automatic tensioning and rotating unit; the rotatory piece of tensioning include well pipe, with well pipe normal running fit's rotatory pipe, with rotatory pipe side complex tensioning lever, make the tensioning lever with the fastener of rotatory pipe side laminating, simultaneously with rotatory pipe reaches fastener complex differential mechanism, with differential mechanism complex driving piece, and with fastener complex chucking spare, well pipe side is prolonged its circumference and is provided with a plurality of extension rods to the array, the tensioning rod set up in the extension rod clearance, the fastener with the extension rod cooperation.

As a preferable embodiment of the automatic fiber winding machine of the present invention, wherein: the side of the rotating pipe is provided with an Archimedes spiral gear, the tensioning rod comprises a meshing block and a tensioning block, the meshing block is perpendicular to the tensioning block, and a face gear meshed with the Archimedes spiral gear is arranged on the meshing block.

As a preferable embodiment of the automatic fiber winding machine of the present invention, wherein: the fastener comprises a concave ring matched with the meshing block, the concave ring comprises a second groove arranged on the side surface and matched with the meshing block, and a first gear meshed with the differential mechanism, and a second gear meshed with the differential mechanism is arranged on the rotating pipe.

As a preferable embodiment of the automatic fiber winding machine of the present invention, wherein: the extension rod is provided with threads, and the fastener further comprises a fastening ring in threaded fit with the extension rod.

As a preferable embodiment of the automatic fiber winding machine of the present invention, wherein: each extension rod is provided with a first groove, and the side face of the rotary pipe is clamped with the first groove.

As a preferable embodiment of the automatic fiber winding machine of the present invention, wherein: the chucking spare include with the fastening block of first gear block, with curb plate threaded connection's threaded rod, and with threaded rod tip fixed connection's turning handle, be provided with on the curb plate with fastening block sliding fit's sliding tray.

As a preferable embodiment of the automatic fiber winding machine of the present invention, wherein: the base is provided with a fourth groove for the side plate to move, and a sliding rod in sliding fit with the side plate.

As a preferable embodiment of the automatic fiber winding machine of the present invention, wherein: the automatic tensioning rotary unit further comprises an automatic separating piece arranged in the base, the automatic separating piece comprises a rack rod matched with the side plate, a third gear meshed with the rack rod and drives a second driving motor rotating by the third gear, and the second driving motor is fixed on the base.

As a preferable embodiment of the automatic fiber winding machine of the present invention, wherein: the side plate is provided with a first hole in running fit with the rotary pipe and a second hole in running fit with the concave ring, and the diameter of the second hole is larger than that of the first hole.

As a preferable embodiment of the automatic fiber winding machine of the present invention, wherein: and a fifth groove for placing the differential and the driving piece is further formed in the side plate, and the fifth groove is communicated with the second hole.

The automatic tensioning and rotating device has the advantages that the automatic tensioning and rotating unit is suitable for glass fiber reinforced plastic sleeves with different diameters, the application range of the machine is greatly increased, the tensioning rod can be contracted and rotated only by arranging one driving device, fewer parts are used, and the cost is lower.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on these drawings without inventive exercise. Wherein:

fig. 1 is a block diagram of an automated fiber winding machine in example 1.

Fig. 2 is a block diagram of an automated tensioning rotary unit of the automated fiber winding machine of example 1.

Fig. 3 is a block diagram of the tensioning rotary of the automated fiber winding machine of example 1.

Fig. 4 is an exploded view of the tensioning rotary member of the automated fiber winding machine of example 1.

Fig. 5 is a schematic view of the tension bar of the automated fiber winding machine of example 1.

Fig. 6 is a diagram of a concave ring structure of the automated fiber winding machine of example 1.

Fig. 7 is a side plate structure view of the automatic fiber winding machine in example 2.

Fig. 8 is a schematic view of a fifth groove of the automated fiber winding machine of example 2.

Fig. 9 is a structural view of an automatic separator of the automatic fiber winding machine in example 2.

Fig. 10 is a top view of an automated tension rotary unit of the automated fiber winding machine of example 2.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, but the present invention may be practiced in other ways than those specifically described and will be readily apparent to those of ordinary skill in the art without departing from the spirit of the present invention, and therefore the present invention is not limited to the specific embodiments disclosed below.

Furthermore, reference herein to "one embodiment" or "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one implementation of the invention. The appearances of the phrase "in one embodiment" in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

Example 1

Referring to fig. 1 to 6, a first embodiment of the present invention provides an automatic fiber winding machine, which includes an automatic tensioning rotary unit 100 and a fiber winding unit 200, wherein the automatic tensioning rotary unit 100 fixes and rotates a glass fiber reinforced plastic sleeve, and the fiber winding unit 200 supplies fiber to glass fiber reinforced plastic.

Specifically, the automatic tensioning rotary unit 100 includes side plates 101 symmetrically arranged, a base 102 engaged with the side plates 101, and a tensioning rotary member 103 arranged inside the side plates 101. The tensioning rotary member 103 comprises a middle pipe 103a, a rotary pipe 103b in running fit with the middle pipe 103a, a tensioning rod 103c in side fit with the rotary pipe 103b, a fastener 103d for enabling the tensioning rod 103c to be attached to the side of the rotary pipe 103b, a differential 103e matched with the rotary pipe 103b and the fastener 103d, a driving member 103f matched with the differential 103e, and a clamping member 103g matched with the fastener 103d, wherein the side of the middle pipe 103a is provided with a plurality of extension rods 103a-1 along the circumferential array thereof, the tensioning rod 103c is arranged in a gap between the extension rods 103a-1, and the fastener 103d is matched with the extension rods 103 a-1. In this embodiment, the driving member 103f is a motor, and the output end of the motor is connected to a bevel gear, which is connected to the differential 103 e.

The filament winding unit 200 is disposed corresponding to the automatic tension rotating unit 100, and the filament winding unit 200 may be an existing filament supplying device, and it should be noted that the device may be moved back and forth, so that the glass fiber reinforced plastic may be uniformly wound.

Further, an archimedes spiral gear 103b-1 is arranged on the side surface of the rotating pipe 103b, the tension rod 103c comprises an engagement block 103c-1 and a tension block 103c-2, the engagement block 103c-1 is arranged perpendicular to the tension block 103c-2, a face gear 103c-11 engaged with the archimedes spiral gear 103b-1 is arranged on the engagement block 103c-1, the tension rod 103c is tightly attached to the rotating pipe 103b, and when the rotating pipe 103b rotates, the tension rod 103c can move up and down.

Preferably, the fastening member 103d includes a concave ring 103d-1 engaged with the engaging block 103c-1, the concave ring 103d-1 includes a second concave groove 103d-11 laterally disposed and engaged with the engaging block 103c-1, and a first gear 103d-12 engaged with the differential 103e, and the rotating tube 103b is provided with a second gear 103b-2 engaged with the differential 103 e.

Preferably, the extension rod 103a-1 is provided with threads, and the fastener 103d further comprises a fastening ring 103d-2 that is threadedly engaged with the extension rod 103 a-1. The number of the tension rods 103c is at least 3, the number of the tension rods 103c is closely related to the firmness of the glass fiber reinforced plastic sleeve, the larger the number of the tension rods 103c is, the larger the contact area with the inner wall of the glass fiber reinforced plastic sleeve is, the more stable the glass fiber reinforced plastic sleeve can be, preferably, the multilayer rubber pads are arranged on the upper surface of the tension block 103c-2, so that the friction force can be increased, and the glass fiber reinforced plastic sleeve can be prevented from being broken by the tension block 103 c-2.

Furthermore, each extension rod 103a-1 is provided with a first groove 103a-11, and the side surface of the rotating pipe 103b is engaged with the first groove 103 a-11.

Preferably, the clamping member 103g comprises a fastening block 103g-1 engaged with the first gear 103d-12, a threaded rod 103g-2 threadedly coupled to the side plate 101, and a rotating handle 103g-3 fixedly coupled to an end of the threaded rod 103g-2, and the side plate 101 is provided with a sliding groove 101a slidably engaged with the fastening block 103 g-1.

In summary, the rotary tube 103b is sleeved on the middle tube 103a, the side surface thereof is disposed in the first groove 103a-11 of the extension rod 103a-1, the Archimedes spiral gear 103b-1 is disposed on one side of the rotary tube 103b, the tension rod 103c is engaged with the Archimedes spiral gear 103b-1, and the tension rod 103c is tightly attached to the rotary tube 103b by the fastener 103 d. The rotating pipe 103b and the concave ring 103d-1 are both provided with gears meshed with the differential 103e, when the clamping piece 103g is clamped with the first gear 103d-12 on the concave ring 103d-1, the driving piece 103f can only drive the rotating pipe 103b to rotate under the action of the differential 103e, at the moment, the tensioning rod 103c can stretch and contract, and when the clamping piece 103g is separated from the first gear 103d-12, the driving piece 103f drives the rotating pipe 103b and the fastening piece 103d to integrally rotate through the differential 103 e.

When the fiber winding device is used, the glass fiber reinforced plastic sleeve is sleeved on the tensioning rod 103c, the rotating handle 103g-3 is screwed, the clamping piece 103g is clamped with the first gear 103d-12, the driving piece 103f drives the differential mechanism 103e to rotate, the tensioning rod 103c fixes the glass fiber reinforced plastic sleeve, then the rotating handle 103g-3 is screwed, after the clamping piece 103g is separated from the first gear 103d-12, fibers on the fiber winding unit 200 are connected to the glass fiber reinforced plastic sleeve, and the driving piece 103f drives the differential mechanism 103e to rotate, so that the glass fiber reinforced plastic sleeve rotates and is wound.

Example 2

Referring to fig. 7 to 10, a second embodiment of the present invention is different from the first embodiment in that: the automated tensioning rotary unit 100 also includes an autosegregation piece 104. In the above embodiment, the automatic fiber winding machine includes an automatic tension rotating unit 100 and a fiber winding unit 200, the automatic tension rotating unit 100 realizes the fixing and rotation of the glass fiber reinforced plastic sleeve, and the fiber winding unit 200 realizes the fiber supply of the glass fiber reinforced plastic.

Specifically, the automatic tensioning rotary unit 100 includes side plates 101 symmetrically arranged, a base 102 engaged with the side plates 101, and a tensioning rotary member 103 arranged inside the side plates 101. The tensioning rotary member 103 comprises a middle pipe 103a, a rotary pipe 103b in running fit with the middle pipe 103a, a tensioning rod 103c in side fit with the rotary pipe 103b, a fastener 103d for enabling the tensioning rod 103c to be attached to the side of the rotary pipe 103b, a differential 103e matched with the rotary pipe 103b and the fastener 103d, a driving member 103f matched with the differential 103e, and a clamping member 103g matched with the fastener 103d, wherein the side of the middle pipe 103a is provided with a plurality of extension rods 103a-1 along the circumferential array thereof, the tensioning rod 103c is arranged in a gap between the extension rods 103a-1, and the fastener 103d is matched with the extension rods 103 a-1.

The filament winding unit 200 is disposed corresponding to the automatic tension rotation unit 100.

An Archimedes spiral gear 103b-1 is arranged on the side surface of the rotating pipe 103b, the tensioning rod 103c comprises an engaging block 103c-1 and a tensioning block 103c-2, the engaging block 103c-1 is perpendicular to the tensioning block 103c-2, and a face gear 103c-11 meshed with the Archimedes spiral gear 103b-1 is arranged on the engaging block 103 c-1.

The fastening member 103d comprises a concave ring 103d-1 matched with the engaging block 103c-1, the concave ring 103d-1 comprises a second concave groove 103d-11 matched with the engaging block 103c-1 and arranged on the side surface, and a first gear 103d-12 engaged with the differential gear 103e, and a second gear 103b-2 engaged with the differential gear 103e is arranged on the rotating pipe 103 b.

The extension rod 103a-1 is provided with threads, and the fastener 103d further comprises a fastening ring 103d-2 which is in threaded engagement with the extension rod 103 a-1.

Each extension rod 103a-1 is provided with a first groove 103a-11, and the side surface of the rotary pipe 103b is clamped with the first groove 103 a-11. The clamping piece 103g comprises a fastening block 103g-1 engaged with the first gear 103d-12, a threaded rod 103g-2 in threaded connection with the side plate 101, and a rotating handle 103g-3 fixedly connected with the end of the threaded rod 103g-2, and the side plate 101 is provided with a sliding groove 101a in sliding fit with the fastening block 103 g-1.

Further, a fourth groove 102a for moving the side plate 101 and a sliding rod 102b slidably engaged with the side plate 101 are provided on the base 102.

Preferably, the side plate 101 is provided with a first hole 101b rotatably engaged with the rotary tube 103b and a second hole 101c engaged with the concave ring 103d-1, the diameter of the second hole 101c is larger than that of the first hole 101b, the side plate 101 is further provided with a fifth groove 101d for placing the differential 103e and the driving member 103f, and the fifth groove 101d is communicated with the second hole 101 c. This has the advantage of facilitating removal of the tension rod 103 c.

The automatic tensioning and rotating unit 100 further comprises an automatic separating part 104 arranged in the base 102, wherein the automatic separating part 104 comprises a rack bar 104a matched with the side plate 101, a third gear 104b meshed with the rack bar 104a, and a second driving motor 104c driving the third gear 104b to rotate, and the second driving motor 104c is fixed on the base 102. That is, the second driving motor 104c rotates to move the two side plates 101 in opposite directions, thereby facilitating the assembly and disassembly of the glass fiber reinforced plastic sleeve.

When the fiber winding device is used, the second driving motor 104c is rotated to enable the two side plates 101 to be far away, then the glass fiber reinforced plastic sleeve is moved to a corresponding position, then the second driving motor 104c enables the side plates 101 to move oppositely, the tensioning rod 103c is inserted into the glass fiber reinforced plastic sleeve, the rotating handle 103g-3 is screwed, after the clamping piece 103g is clamped with the first gear 103d-12, the driving piece 103f drives the differential mechanism 103e to rotate, the tensioning rod 103c fixes the glass fiber reinforced plastic sleeve, then the rotating handle 103g-3 is screwed, when the clamping piece 103g is separated from the first gear 103d-12, fibers on the fiber winding unit 200 are connected to the glass fiber reinforced plastic sleeve, and then the driving piece 103f drives the differential mechanism 103e to rotate, so that the glass fiber reinforced plastic sleeve rotates and is wound.

It should be noted that the above-mentioned embodiments are only for illustrating the technical solutions of the present invention and not for limiting, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications or equivalent substitutions may be made on the technical solutions of the present invention without departing from the spirit and scope of the technical solutions of the present invention, which should be covered by the claims of the present invention.

Claims (10)

1. An automatic chemical fiber winding machine is characterized in that: comprises the steps of (a) preparing a mixture of a plurality of raw materials,

the automatic tensioning rotary unit (100) comprises side plates (101) which are symmetrically arranged, a base (102) matched with the side plates (101), and a tensioning rotary piece (103) arranged inside the side plates (101); and the number of the first and second groups,

a filament winding unit (200) provided corresponding to the automatic tension rotation unit (100);

the tensioning rotating piece (103) comprises a middle pipe (103a), a rotating pipe (103b) in running fit with the middle pipe (103a), a tensioning rod (103c) matched with the side surface of the rotating pipe (103b), a fastening piece (103d) enabling the tensioning rod (103c) to be attached to the side surface of the rotating pipe (103b), a differential mechanism (103e) matched with the rotating pipe (103b) and the fastening piece (103d) simultaneously, and a driving piece (103f) matched with the differential mechanism (103e), and a clamping member (103g) which is matched with the fastening member (103d), the side surface of the middle pipe (103a) is provided with a plurality of extension rods (103a-1) along the circumferential array thereof, the tension rod (103c) is arranged in the gap of the extension rod (103a-1), and the fastener (103d) is matched with the extension rod (103 a-1).

2. The automated filament winding machine of claim 1, wherein: an Archimedean spiral gear (103b-1) is arranged on the side face of the rotating pipe (103b), the tensioning rod (103c) comprises an engagement block (103c-1) and a tensioning block (103c-2), the engagement block (103c-1) and the tensioning block (103c-2) are vertically arranged, and a face gear (103c-11) engaged with the Archimedean spiral gear (103b-1) is arranged on the engagement block (103 c-1).

3. The automated filament winding machine of claim 2, wherein: the fastener (103d) comprises a concave ring (103d-1) matched with the engagement block (103c-1), the concave ring (103d-1) comprises a second concave groove (103d-11) which is arranged on the side surface and matched with the engagement block (103c-1), and a first gear (103d-12) meshed with the differential mechanism (103e), and a second gear (103b-2) meshed with the differential mechanism (103e) is arranged on the rotating pipe (103 b).

4. An automated fiber winding machine according to claim 3, characterized in that: the extension rod (103a-1) is provided with threads, and the fastener (103d) further comprises a fastening ring (103d-2) in threaded fit with the extension rod (103 a-1).

5. An automated fiber winding machine according to claim 3 or 4, characterized in that: each extension rod (103a-1) is provided with a first groove (103a-11), and the side surface of the rotary pipe (103b) is clamped with the first groove (103 a-11).

6. The automated filament winding machine of claim 5, wherein: the clamping piece (103g) comprises a fastening block (103g-1) clamped with the first gear (103d-12), a threaded rod (103g-2) in threaded connection with the side plate (101), and a rotating handle (103g-3) fixedly connected with the end of the threaded rod (103g-2), wherein a sliding groove (101a) in sliding fit with the fastening block (103g-1) is formed in the side plate (101).

7. An automated filament winding machine according to any one of claims 3, 4 or 6, wherein: the base (102) is provided with a fourth groove (102a) for the side plate (101) to move, and a sliding rod (102b) in sliding fit with the side plate (101).

8. The automated fiber winding machine of claim 7, wherein: the automatic tensioning and rotating unit (100) further comprises an automatic separating piece (104) arranged in the base (102), the automatic separating piece (104) comprises a rack rod (104a) matched with the side plate (101), a third gear (104b) meshed with the rack rod (104a), and a second driving motor (104c) driving the third gear (104b) to rotate, and the second driving motor (104c) is fixed on the base (102).

9. An automated fiber winding machine according to any one of claims 3, 4, 6 or 8, wherein: the side plate (101) is provided with a first hole (101b) which is in running fit with the rotary pipe (103b) and a second hole (101c) which is matched with the concave ring (103d-1), and the diameter of the second hole (101c) is larger than that of the first hole (101 b).

10. The automated filament winding machine of claim 9, wherein: and a fifth groove (101d) for placing the differential (103e) and the driving piece (103f) is further formed in the side plate (101), and the fifth groove (101d) is communicated with the second hole (101 c).

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