CN214495049U - A winding structure for cotton processingequipment of pearl - Google Patents

Abstract

The application discloses rolling structure for cotton processingequipment of pearl, including rotary drive subassembly, winding drum and winding core, the rolling structure of this application can peg graft the cotton tip of pearl in the bar rolling opening on the winding drum and the bar winding inslot on the winding core in proper order, through setting up the winding core and along predetermineeing the rotatory angle of predetermineeing of direction after, the bar flange on the winding core can be portable to with the cotton butt of pearl and promote the cotton and holding chamber wall face butt of pearl to fixed cotton tip of pearl. The friction force between the surface of the pearl wool and the surfaces of the strip-shaped flange and the wall surface of the containing cavity can drive the end part of the pearl wool to rotate along with the strip-shaped flange, so that the end part of the pearl wool can be clamped between the strip-shaped flange and the wall surface of the containing cavity more. When the winding core is rotated in the opposite direction of the preset direction, the clamped pearl cotton can be taken out to buffer the pretightening force for preventing the pearl cotton from being loose and enabling the pearl cotton to be tightly attached to the surface of the winding core in the winding process, so that the wound pearl cotton can be conveniently taken down from the winding structure.

Description

A winding structure for cotton processingequipment of pearl

Technical Field

The application relates to the technical field of pearl cotton processing, in particular to a rolling structure for a pearl cotton processing device.

Background

The polyethylene foam cotton is a non-crosslinked closed-cell structure, is also called EPE pearl cotton, is formed by countless independent bubbles generated by physically foaming low-density polyethylene ester, overcomes the defects of fragility, deformation and poor recovery of common foam rubber, has the advantages of water resistance, moisture resistance, shock resistance, sound insulation, heat preservation, good plasticity, strong toughness, cyclic reconstruction, environmental protection, strong impact resistance and the like, also has good chemical resistance, and is an ideal substitute of the traditional packaging material.

In the production and processing process of the pearl cotton coiled material, the produced pearl cotton coiled material needs to be rolled so as to reduce the storage space, and the pearl cotton coiled material is convenient to carry, transport, subsequently cut and the like. Because the pearl cotton itself has certain elasticity and toughness and is difficult to be stereotyped, and the pearl cotton is light easy to float to and the pearl cotton has certain width and leads to its tip to be great by the fixed area, these special conditions will lead to the pearl cotton tip to be difficult to be fixed in on the wind-up roll of coiling mechanism, influence the coiling efficiency of coiling mechanism to the pearl cotton.

SUMMERY OF THE UTILITY MODEL

The application provides a rolling structure for cotton processingequipment of pearl can solve the cotton processing in-process pearl cotton tip of pearl and be difficult to by fixed technical problem, improves the cotton rolling efficiency of pearl.

The application provides a rolling structure for cotton processingequipment of pearl, including rotation driving subassembly, receipts reel and receipts roll core. The winding drum comprises a first end and a second end which are arranged oppositely along the axial direction of the winding drum, the first end is installed at the driving end of the rotary driving component, an accommodating cavity with a circular cross section is arranged in the winding drum along the axial direction of the winding drum, and a strip-shaped winding opening communicated with the accommodating cavity is arranged on the winding drum along the axial parallel direction of the winding drum. The rolling core is arranged in the accommodating cavity in a penetrating mode after penetrating through the second end, the rolling core is rotatably accommodated in the accommodating cavity, the central shaft of the rolling core is overlapped with the central line of the accommodating cavity, the rolling core is provided with a strip-shaped rolling groove along the direction parallel to the axial direction of the rolling core, the strip-shaped rolling groove is in butt joint with the strip-shaped rolling opening and used for bearing the end portion, passing through the strip-shaped rolling opening, of the pearl cotton, a strip-shaped flange connected with the strip-shaped rolling groove is arranged on the rolling core along the direction parallel to the axial direction of the rolling core, and the strip-shaped flange is arranged on the rolling core and used for driving the pearl cotton to abut against the wall surface of the accommodating cavity after rotating to a preset angle along the preset direction.

In some exemplary embodiments, the winding structure further includes a limiting component for preventing the winding core from rotating relative to the winding drum along the axial direction thereof as a central axis, and two ends of the limiting component are respectively connected with the second end and the end of the winding core.

In some exemplary embodiments, the limiting component comprises a buckle, one end of the buckle is provided with a clamping block, the second end surface of the winding drum is provided with a clamping groove, and the other end of the buckle is rotatably installed on the surface of the winding core close to the second end so as to clamp the clamping block in the clamping groove.

In some exemplary embodiments, the winding core comprises a main shaft and a plurality of annular flanges arranged on the main shaft side by side along the length direction of the main shaft, the surfaces of the annular flanges are attached to the wall surface of the accommodating cavity, the winding core further comprises a protruding strip arranged on the main shaft side by side and connected with the strip-shaped flanges, the plurality of annular flanges are connected with the strip-shaped flanges and the protruding strip, and the strip-shaped winding grooves are arranged at the end parts of the protruding strip.

In some exemplary embodiments, one end of the main shaft adjacent to the first end is connected with the wall surface of the accommodating cavity, and the other end of the main shaft adjacent to the second end extends out of the annular flange surface in a plane perpendicular to the axial direction of the main shaft, and the annular flange surface adjacent to the second end is flush with the second end surface.

In some exemplary embodiments, the strip-shaped roll opening end extends to connect with a surface of the second end.

In some exemplary embodiments, the surface of the annular flange, which is attached to the wall surface of the accommodating cavity, is a circular arc surface.

In some exemplary embodiments, the wall surface of the strip-shaped flange for connecting with the pearl wool is an arc surface with the radius gradually decreasing towards the strip-shaped rolling groove, and the wall surface of the strip-shaped rolling groove connected with the strip-shaped flange is an inclined surface with the inner diameter gradually decreasing along the direction away from the strip-shaped flange.

In some exemplary embodiments, the winding drum is provided with an arc-shaped guide surface connected with one opening edge of the strip-shaped winding opening, and the radius of the arc-shaped guide surface is gradually reduced along the direction of the strip-shaped winding opening.

In some exemplary embodiments, the rotary drive assembly includes a rotary drive motor and a mounting plate mounted to a drive end of the rotary drive motor, the first end being mounted to the mounting plate.

The application provides a rolling structure for cotton processingequipment of pearl can peg graft the cotton tip of pearl in the bar rolling opening on the receipts reel and the bar on the rolling core in proper order and receive the roll up the inslot, through setting up to receive the roll core along the rotatory angle of predetermineeing of direction, the bar flange on the rolling core can move to with the cotton butt of pearl and promote the cotton and holding chamber wall face butt of pearl to fixed cotton tip of pearl. The friction force between the surface of the pearl cotton and the surfaces of the strip-shaped flange and the wall surface of the containing cavity can drive the end part of the pearl cotton to rotate along with the strip-shaped flange, so that the end part of the pearl cotton can be clamped between the strip-shaped flange and the wall surface of the containing cavity more. When the winding core is rotated in the opposite direction of the preset direction, the butt joint of the strip-shaped flange on the pearl cotton can be removed, the pearl cotton contained between the strip-shaped flange and the wall surface of the containing cavity before being taken out is taken out, and the taken-out pearl cotton can be used for buffering the pretightening force for preventing the pearl cotton from being tightly attached to the surface of the winding core for loosening prevention in the winding process so as to take the wound pearl cotton down from the winding structure.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a schematic perspective view of a rolling structure for a pearl wool processing device in an embodiment of the present application;

fig. 2 is a schematic perspective view of a winding core according to an embodiment of the present application;

FIG. 3 is a side view of a take-up core installed in a take-up spool in one embodiment of the present application;

FIG. 4 is a side view of a roll core installed in a roll core in another embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the present application more apparent, the present application is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present application and are not intended to limit the present application.

The rolling structure for cotton processingequipment of pearl that this application embodiment provided can be used to pull the pearl cotton and drive the cotton rolling of pearl in this is structural to the cotton accomodating and transporting of pearl. As shown in fig. 1 to 4, the winding structure for a pearl wool processing device of the present application includes a rotary driving assembly 100, a winding drum 200 and a winding core 300.

The winding drum 200 comprises a first end 210 and a second end 220 which are oppositely arranged along the axial direction of the winding drum 200, the first end 210 is installed at the driving end of the rotary driving component 100, an accommodating cavity 230 with a circular cross section is arranged in the winding drum 200 along the axial direction, and a strip-shaped winding opening 240 communicated with the accommodating cavity 230 is arranged on the winding drum 200 along the axial direction in parallel. The winding core 300 is rotatably accommodated in the accommodating cavity 230 after penetrating through the second end 220, a central axis of the winding core 300 is overlapped with a central line of the accommodating cavity 230, a strip-shaped winding groove 310 is formed in the winding core 300 along the axial parallel direction of the winding core, the strip-shaped winding groove 310 is in butt joint with the strip-shaped winding opening 240 and is used for receiving the end part of the pearl cotton 500 penetrating through the strip-shaped winding opening 240, a strip-shaped flange 320 connected with the strip-shaped winding groove 310 is arranged on the winding core 300 along the axial parallel direction of the winding core, and the strip-shaped flange 320 is used for driving the pearl cotton 500 to abut against the wall surface of the accommodating cavity 230 after the winding core 300 rotates to a preset angle along the preset direction.

The rolling structure for the pearl cotton processing device provided by the embodiment of the application is characterized in that the rolling structure is provided with the strip rolling opening 240 on the rolling cylinder 200, and the rolling core 300 is provided with the strip rolling groove 310 butted with the strip rolling opening 240, so that the end part of the pearl cotton 500 can pass through the strip rolling opening 240 and then be continuously accommodated in the strip rolling groove 310. The winding core 300 can rotate in the accommodating cavity 230 of the winding drum 200, and the strip-shaped flange 320 is arranged on the winding core 300, so that after the winding core 300 rotates for a preset angle along a preset direction, the strip-shaped flange 320 can move to abut against the pearl wool 500 and push the pearl wool 500 to abut against the wall surface of the accommodating cavity 230, and thus the end part of the pearl wool 500 is fixed between the winding drum 200 and the winding core 300. After the end of the pearl wool 500 is fixed, the rotation driving assembly 100 is controlled to operate to drive the winding drum 200 and the winding core 300 to rotate together, so that the pearl wool 500 is wound on the surface of the winding drum 200.

The strip-shaped flange 320 drives the pearl wool 500 to abut against the wall surface of the accommodating cavity 230, and when the rolling core 300 rotates along the preset direction, the friction force between the surface of the strip-shaped flange 320 and the wall surface of the accommodating cavity 230 and the surface of the pearl wool 500 can drive the end of the pearl wool 500 to rotate along with the strip-shaped flange 320, so that the end of the pearl wool 500 can be accommodated between the strip-shaped flange 320 and the wall surface of the accommodating cavity 230 more. When the pearl cotton 500 is fully wound on the winding drum 200 and the pearl cotton 500 needs to be taken down, the winding drum 300 can be rotated in the direction opposite to the preset direction, the abutting of the strip-shaped flange 320 on the pearl cotton 500 is released, the pearl cotton 500 which is accommodated between the strip-shaped flange 320 and the wall surface of the accommodating cavity 230 can be taken out along with the rotation of the strip-shaped flange 320, and the taken-out pearl cotton 500 can be used for buffering the pre-tightening force which enables the pearl cotton 500 at the bottom layer to cling to the surface of the winding drum 200 for loosening prevention in the winding process, so that the wound pearl cotton 500 can be taken down from the winding structure.

In some exemplary embodiments, the rotation driving assembly 100 includes a rotation driving motor 110 and a mounting plate 120 mounted at a driving end of the rotation driving motor 110, the first end 210 of the winding drum 200 is mounted on the mounting plate 120, and controlling the rotation driving motor 110 to rotate the mounting plate 120 and thus the winding drum 200 and the winding core 300.

In some exemplary embodiments, the winding structure further comprises a limiting assembly 400, and both ends of the limiting assembly 400 are respectively connected with the second end 220 and the end of the winding core 300 adjacent to the second end 220 to prevent the winding core 300 from rotating relative to the winding core 200 along the axial direction thereof as a central axis. Through setting up spacing subassembly 400, can fix the position of receipts core 300 in winding reel 200, prevent that receipts core 300 from rotating at will in winding reel 200 to maintain bar flange 320 and the holding chamber 230 wall to the cotton 500 clamping stability of pearl.

As shown in fig. 2 and 3, in some exemplary embodiments, the limiting assembly 400 may include a buckle 410, one end of the buckle 410 is provided with a latch 411, the surface of the second end 220 of the winding roll 200 is provided with a locking groove 250, and the other end of the buckle 410 is rotatably mounted on the surface of the winding roll 300 near the second end 220 to lock the latch 411 in the locking groove 250, so as to prevent the winding roll 300 from rotating relative to the winding roll 200 about the axial direction thereof as a central axis and prevent the winding roll 300 from being removed from the accommodating cavity 230. The number of the limiting assemblies 400 can be set to be multiple groups and are uniformly arranged on the winding core 300, so that the positions of the winding core 300 and the winding roll 200 are fully limited. Specifically, the winding core 300 may be provided with a mounting seat 420, and an end of the buckle 410 may be hinged to the mounting seat 420.

The position of draw-in groove 250 for bar rolling opening 240 is adjusted to the accessible to regulation and control rolls up core 300 along the rotatory angle of predetermineeing the direction. Further, still can be through the position of regulation and control draw-in groove 250, make hasp 410 joint in draw-in groove 250 after, the interval between bar flange 320 and the holding chamber 230 wall can make bar flange 320 act on the butt power of the cotton 500 of pearl just drive the cotton 500 of pearl and remove can to prevent that the interval between bar flange 320 and the holding chamber 230 wall is undersized excessively extrudees the cotton 500 of pearl, avoids the cotton 500 of pearl that is produced irreversible deformation by the centre gripping and causes the waste.

In some exemplary embodiments, as shown in fig. 2, the winding core 300 includes a main shaft 330 and a plurality of annular flanges 340 installed on the main shaft 330 side by side along a length direction of the main shaft 330, a surface of the annular flange 340 is attached to a wall surface of the accommodating cavity 230, the winding core 300 further includes a protruding strip 350 installed on the main shaft 330 side by side and connected to the strip-shaped flange 320, the plurality of annular flanges 340 are connected to the strip-shaped flange 320 and the protruding strip 350, and the strip-shaped winding slots 310 are installed at ends of the protruding strip 350. The winding core 300 can smoothly rotate in the winding drum 200 by providing the annular flange 340, the strip-shaped flange 320 and the protruding strip 350 on the winding core 300. And the surface of the annular flange 340 is attached to the wall surface of the accommodating cavity 230, so that the contact area between the winding core 300 and the wall surface of the accommodating cavity 230 can be effectively reduced, the friction force between the winding core 300 and the wall surface of the accommodating cavity 230 is reduced, and the winding core 300 can smoothly rotate in the accommodating cavity 230.

On the basis that the annular flange 340 is attached to the wall surface of the accommodating cavity 230 so that the rolling core 300 can rotate smoothly in the accommodating cavity 230, preferably, in some exemplary embodiments, the surface of the annular flange 340 attached to the wall surface of the accommodating cavity 230 is an arc surface, so that the area of the annular flange 340 contacting with the wall surface of the accommodating cavity 230 is further reduced, the driving force required for driving the rolling core 300 to rotate is reduced, the rolling core 300 is easy to rotate, and the operability of clamping the end portion of the pearl wool 500 by the rolling mechanism is improved.

In some exemplary embodiments, the surface of the annular flange 340 adjacent to the second end 220 is flush with the surface of the second end 220 in a plane perpendicular to the axial direction of the main shaft 330, so that the latch 411 can be smoothly rotated into the latch slot 250 on the take-up spool 200 after the buckle 410 is mounted on the annular flange 340 at the end. One end of the main shaft 330 near the first end 210 can be connected with the wall surface of the accommodating cavity 230, the other end of the main shaft 330 near the second end 220 can extend out of the surface of the annular flange 340, further, in a plane perpendicular to the axial direction of the main shaft 330, the cross section of the main shaft 330 can be set to be circular, the cross section of the end part of the main shaft 330 extending out of the accommodating cavity 230 can be set to be smaller than the area of the cross section of the main shaft 330 in the accommodating cavity 230, and a transition surface connecting two different cross sections on the main shaft 330 can be flush with the surface of the annular flange 340 at the end part, so that the installation of the limiting assembly 400 is facilitated, and more installation space is reserved for the limiting assembly 400.

The main shaft 330 may be provided with a guide block 360 extending out of the receiving cavity 230 for holding the main shaft 330, for example, two guide blocks 360 are oppositely arranged on the periphery of the main shaft 330 for acting on the two guide blocks 360 in a direction perpendicular to the axial direction of the main shaft 330 to push the main shaft 330 to rotate.

The width of the strip-shaped rolling opening 240 may be set to be greater than or equal to the thickness of the pearl wool 500, and preferably, the width of the strip-shaped rolling opening 240 may be set to be greater than the thickness of the pearl wool 500, so that the pearl wool 500 can smoothly pass through the strip-shaped rolling opening 240.

In some exemplary embodiments, the end of the strip-shaped rolling opening 240 extends to be connected with the surface of the second end 220, so that the end of the pearl wool 500 passing through the strip-shaped rolling opening 240 can be moved out of the strip-shaped rolling opening 240 along the length direction of the strip-shaped rolling opening 240, and the pearl wool 500 can be conveniently removed from the rolling cylinder 200. When the depth of the strip-shaped rolling groove 310 is adjusted, one end of the strip-shaped rolling groove 310 close to the second end 220 is also communicated with the surface of the main shaft 330, so that the smoothness of the pearl cotton 500 moving out from the strip-shaped rolling opening 240 is further improved.

In some exemplary embodiments, the take-up reel 200 is provided with an arc-shaped guide surface 260 connected to one of the opening edges of the strip take-up opening 240, and the arc-shaped guide surface 260 is configured such that the radius thereof gradually decreases in the direction of the strip take-up opening 240. Through setting up arc spigot surface 260, can lead to the moving direction of cotton 500 of pearl, the cotton 500 of pearl of being convenient for smoothly pegs graft in bar rolling opening 240.

The strip-shaped winding groove 310 is arranged in the direction perpendicular to the winding core 300 to have a certain depth so that the end part of the pearl cotton 500 can be stably placed in the strip-shaped winding groove 310, and the strip-shaped flange 320 can act on the surface of the pearl cotton 500 to drive the end part of the pearl cotton 500 to move between the surface of the strip-shaped flange 320 and the wall surface of the accommodating cavity 230 when the winding core 300 rotates, so that the pearl cotton 500 is fixed conveniently.

In some exemplary embodiments, the wall surface of the strip-shaped flange 320 for contacting with the pearl cotton is configured as an arc surface with a gradually decreasing radius towards the strip-shaped rolling groove 310, and the wall surface of the strip-shaped rolling groove 310 connected with the strip-shaped flange 320 is configured as an inclined surface with a gradually decreasing inner diameter along the direction away from the strip-shaped flange 320, so that the pearl cotton 500 can smoothly enter the strip-shaped rolling groove 310, and the convenience of installing the pearl cotton 500 in the strip-shaped rolling groove 310 is improved. In addition, the inclined plane that the bar-shaped coiling groove 310 along keeping away from bar flange 320 direction internal diameter reduces gradually, when rolling core 300 is rotatory, the inclined plane of bar-shaped coiling groove 310 can be followed and is predetermine the direction that the direction is the contained angle and act on the cotton 500 surface of pearl, and then can assist bar flange 320 to drive the cotton 500 of pearl and hold the chamber 230 wall butt.

The same or similar reference numerals in the drawings of the present embodiment correspond to the same or similar components; in the description of the present application, it is to be understood that if there is an orientation or positional relationship indicated by the terms "upper", "lower", "left", "right", etc. based on the orientation or positional relationship shown in the drawings, it is only for convenience of description and simplification of description, but it is not intended to indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and therefore, the terms describing the positional relationship in the drawings are only for illustrative purposes and are not to be construed as limitations of the present patent, and specific meanings of the above terms may be understood by those skilled in the art according to specific situations.

The above description is only exemplary of the present application and should not be taken as limiting the present application, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. The utility model provides a rolling structure for cotton processingequipment of pearl which characterized in that includes:

a rotary drive assembly;

the winding drum comprises a first end and a second end which are oppositely arranged along the axial direction of the winding drum, the first end is arranged at the driving end of the rotary driving component, an accommodating cavity with a circular cross section is arranged in the winding drum along the axial direction of the winding drum, and a strip-shaped winding opening communicated with the accommodating cavity is arranged on the winding drum along the axial direction of the winding drum; and

the winding core is arranged in the accommodating cavity in a penetrating mode after penetrating through the second end and rotatably accommodated in the accommodating cavity, a central shaft of the winding core is overlapped with a central line of the accommodating cavity, a strip-shaped winding groove is formed in the winding core along the direction parallel to the axial direction of the winding core, the strip-shaped winding groove is in butt joint with the strip-shaped winding opening and is used for bearing the end portion of the pearl wool penetrating through the strip-shaped winding opening, a strip-shaped flange connected with the strip-shaped winding groove is arranged on the winding core along the direction parallel to the axial direction of the winding core, and the strip-shaped flange is arranged to enable the winding core to rotate to a preset angle along the preset direction and then is used for driving the pearl wool to abut against the wall surface of the accommodating cavity.

2. The rolling structure for pearl wool processing device according to claim 1, further comprising a limiting component for preventing the rolling core from rotating relative to the rolling core along the axial direction thereof as a central axis, wherein two ends of the limiting component are respectively connected with the second end and the end of the rolling core.

3. The rolling structure for pearl wool processing device as claimed in claim 2, wherein the limiting component comprises a buckle, one end of the buckle is provided with a clamping block, the surface of the second end of the rolling drum is provided with a clamping groove, and the other end of the buckle is rotatably mounted on the surface of the rolling core close to the second end to clamp the clamping block in the clamping groove.

4. The rolling structure for pearl wool processing device according to claim 1, wherein the rolling core comprises a main shaft and a plurality of annular flanges arranged on the main shaft side by side along the length direction of the main shaft, the surface of the annular flange is attached to the wall surface of the accommodating cavity, the rolling core further comprises a convex strip arranged on the main shaft side by side and connected with the strip-shaped flange, the annular flanges are connected with the strip-shaped flange and the convex strip, and the strip-shaped rolling groove is arranged at the end part of the convex strip.

5. The rolling structure for pearl wool processing device according to claim 4, wherein one end of the main shaft adjacent to the first end is connected with the wall surface of the containing cavity, the other end of the main shaft adjacent to the second end extends out of the annular flange surface in a plane perpendicular to the axial direction of the main shaft, and the annular flange surface adjacent to the second end is flush with the second end surface.

6. The rolling structure for pearl wool processing device according to claim 5, wherein the strip-shaped rolling opening end portion extends to be connected with the surface of the second end.

7. The rolling structure for pearl wool processing device according to claim 4, wherein the surface of the annular flange which is attached to the wall surface of the accommodating cavity is a circular arc surface.

8. The rolling structure for the pearl wool processing device according to claim 4, wherein the wall surface of the strip-shaped flange for connecting with the pearl wool is an arc surface with a gradually decreasing radius in the direction of the strip-shaped rolling groove, and the wall surface of the strip-shaped rolling groove connected with the strip-shaped flange is an inclined surface with a gradually decreasing inner diameter in the direction away from the strip-shaped flange.

9. The rolling structure for pearl wool processing device according to claim 1, wherein the rolling drum is provided with an arc-shaped guide surface connected with one opening edge of the strip-shaped rolling opening, and the radius of the arc-shaped guide surface is gradually reduced along the direction of the strip-shaped rolling opening.

10. The rolling structure for pearl wool processing device according to claim 1, wherein the rotation driving assembly comprises a rotation driving motor and a mounting plate mounted at the driving end of the rotation driving motor, the first end being mounted on the mounting plate.

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