CN219194034U - Palm fiber winding mechanism - Google Patents

Abstract

The utility model discloses a palm fiber winding mechanism, which relates to the technical field of palm fiber winding and comprises a base and two supporting frames, wherein the two supporting frames are arranged on the front side and the rear side of the upper end of the base, the upper end faces of the two supporting frames are of inverted isosceles trapezoid structures, rolling grooves are formed in the two sides of the inverted isosceles trapezoid structures, an I-shaped winding shaft for winding palm fibers is rotatably arranged between the two rolling grooves on the same side of the two supporting frames, a rectangular inserting hole is formed in the center of the inverted isosceles trapezoid structure, a rectangular ejector rod is slidably inserted in the rectangular inserting hole and extends to the lower side of the base after slidably penetrating through the base, rollers are rotatably arranged on the top ends of the opposite side walls of the two rectangular ejector rods, a motor is fixedly arranged on the top end of one side wall of one rectangular ejector rod, and the output end of the motor is fixedly connected with the rollers after rotatably penetrating through the rectangular ejector rod. The utility model is convenient for quick replacement of the winding shaft which is full in winding, thereby improving the winding efficiency of palm fibers, well meeting the use demands of people, and being simple and practical.

Description

Palm fiber winding mechanism

Technical Field

The utility model relates to the technical field of palm fiber winding, in particular to a palm fiber winding mechanism.

Background

Palm skin's palm fibre, the usage is extensive, can also make the palm brush, fishing net, rope, palm board bed etc. in the palm fibre production process, need carry out the winding with the palm fibre, among the prior art, the coiling mechanism is when the winding to the palm fibre, is inconvenient for the quick replacement winding full take-up shaft to influence the rolling efficiency of raw materials, can not fine satisfy people's user demand, so this design has produced a palm fibre and has wound a roll mechanism, in order to solve above-mentioned problem.

Disclosure of Invention

The utility model aims to provide a palm fiber winding mechanism for solving the problems in the background technology.

In order to solve the technical problems, the utility model provides the following technical scheme: the utility model provides a palm winding mechanism, includes base and two support frames, two support frames set up both sides around the upper end of base, and two support frame up end is the isosceles trapezoid structure of standing upside down, rolling groove has all been seted up to the both sides of isosceles trapezoid structure of standing upside down, rotates between two rolling grooves of two support frames same one side and is equipped with the I-shaped rolling shaft that is used for winding palm, I-shaped rolling shaft axial both ends rotation joint on two rolling grooves of same side, if so set up, can place two I-shaped rolling shafts on two support frames for rotate the rolling palm simultaneously.

Rectangular inserting holes are formed in the center of the inverted isosceles trapezoid structure, rectangular ejector rods are inserted in the rectangular inserting holes in a sliding mode, the rectangular ejector rods extend to the lower portion of the base after penetrating through the base in a sliding mode, rollers are arranged on the tops of the opposite side walls of the two rectangular ejector rods in a rotating mode, a motor is fixed to the top of one side wall of one rectangular ejector rod, the output end of the motor is fixedly connected with the rollers after penetrating through the rectangular ejector rods in a rotating mode, the two rectangular ejector rods slide downwards along the corresponding rectangular inserting holes after the I-shaped winding shafts are located in the rolling grooves, the two rollers are enabled to roll on the upper end positions between the two I-shaped winding shafts, the motor drives one of the two I-shaped winding shafts to rotate in a rolling mode, and therefore synchronous winding of palm fibers is achieved.

In a further embodiment, the rectangular ejector rod is a counterweight rod.

In a further embodiment, a T-shaped rod is fixed at the bottom end of one rectangular ejector rod side wall, a rectangular cross beam is fixed at the bottom end of the other rectangular ejector rod side wall, and the end part of the rectangular cross beam is in sliding sleeve joint with the T-shaped rod through a T-shaped groove.

In a further embodiment, one of the support brackets is adjustably connected to the upper end surface of the base.

In a further embodiment, an inverted T-shaped chute is formed in the upper end face of the base, an inverted T-shaped adjusting block is fixed to the bottom end face of the support frame, the inverted T-shaped adjusting block is in sliding clamping connection with the inverted T-shaped chute, a plug hole in sliding connection with the rectangular ejector rod is formed in the inverted T-shaped adjusting block, and a matching hole communicated with the inverted T-shaped chute is formed in the bottom end face of the base.

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

the palm fiber winding mechanism can realize synchronous winding of palm fibers by two winding shafts, improves winding efficiency, and is convenient for quick replacement of winding shafts which are full in winding, so that winding efficiency of palm fibers is improved, and using requirements of people are well met, and the palm fiber winding mechanism is simple and practical.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present utility model;

FIG. 2 is a side view in cross-section of a transmission member of an embodiment of the present utility model;

fig. 3 is a cross-sectional view of a base structure according to an embodiment of the present utility model.

In the figure: 1. a base; 11. inverted T-shaped chute; 2. a support frame; 21. an inverted T-shaped adjusting block; 22. a rolling groove; 3. rectangular ejector rods; 31. a motor; 32. a roller; 33. a T-shaped rod; 34. a rectangular cross beam.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1

Referring to fig. 1-3, the present embodiment provides a palm fiber winding mechanism, including a base 1 and two support frames 2, the two support frames 2 are disposed on front and rear sides of an upper end of the base 1, the upper end faces of the two support frames 2 are of inverted isosceles trapezoid structures, rolling grooves 22 are formed on two sides of the inverted isosceles trapezoid structures, an i-shaped winding shaft for winding palm fibers is rotatably disposed between the two rolling grooves 22 on the same side of the two support frames 2, and two axial ends of the i-shaped winding shaft are rotatably clamped on the two rolling grooves 22 on the same side, so that the two i-shaped winding shafts can be disposed on the two support frames 2 for simultaneously rotating and winding palm fibers.

The rolling ball is rotationally arranged on the bottom end surface inside the rolling groove 22, the I-shaped rolling shaft is rotationally clamped in the rolling groove 22, and the friction force generated when the I-shaped rolling shaft rotates is reduced by rotationally attaching the rolling ball to the end part of the I-shaped rolling shaft.

The two I-shaped winding shafts are rotatably arranged on the rolling grooves 22 on the two sides, but are affected by the inverted isosceles trapezoid structure, the two I-shaped winding shafts rotate in real time and are together, and along with the continuous increase of the winding quantity of the I-shaped winding shafts, the end parts of the two I-shaped winding shafts can roll along the inner parts of the rolling grooves 22, so that the winding work of the I-shaped winding shafts on palm fibers is met.

A rectangular inserting hole is formed in the center of the inverted isosceles trapezoid structure, rectangular ejector rods 3 are inserted into the rectangular inserting hole in a sliding mode, the rectangular ejector rods 3 penetrate through the base 1 in a sliding mode and extend to the lower portion of the base 1, rollers 32 are arranged on the tops of the opposite side walls of the two rectangular ejector rods 3 in a rotating mode, a motor 31 is fixed to the top of one side wall of one rectangular ejector rod 3, the output end of the motor 31 penetrates through the rectangular ejector rods 3 in a rotating mode and then is fixedly connected with the rollers 32, when the I-shaped winding shafts are located in the rolling grooves 22, the two rectangular ejector rods 3 slide downwards along the corresponding rectangular inserting holes respectively, the two rollers 32 roll and press the upper end positions between the two I-shaped winding shafts, and the motor 31 drives one of the rollers 32 to rotate, so that the two I-shaped winding shafts can be driven to rotate synchronously, and palm fibers are wound synchronously.

After the I-shaped winding shaft is fully wound with palm fibers, the rectangular ejector rod 3 is lifted upwards, the roller 32 can be far away from the I-shaped winding shaft, so that the I-shaped winding shaft wound with palm fibers can be directly lifted from the rolling groove 22, and then a new I-shaped winding shaft is rotationally clamped in the rolling groove 22 for winding the palm fibers again, so that the winding shaft fully wound is quickly replaced, the winding efficiency of the palm fibers is improved, and the use requirements of people are well met.

The rectangular ejector rod 3 is a counterweight rod, so that the rectangular ejector rod 3 is used as a counterweight, the roller 32 can be stably pressed on the I-shaped rolling shaft in a rolling way, and the friction force of the roller 32 when the roller 32 is pressed on the I-shaped rolling shaft in a rotating way is increased.

One of them rectangle ejector pin 3 lateral wall bottom is fixed with T type pole 33, and another rectangle ejector pin 3 lateral wall bottom is fixed with rectangle crossbeam 34, and rectangle crossbeam 34 tip is through T type groove and the slip socket of T type pole 33, utilizes the slip socket between T type pole 33 and the rectangle crossbeam 34, can link two rectangle ejector pins 3, slides simultaneously along two rectangle spliced eye to the position of two gyro wheels 32 of synchronous adjustment of being convenient for.

One of them support frame 2 is connected with the adjustable of base 1 up end, and another support frame 2 position does not change, can adjust the clearance size between two support frames 2 like this to satisfy the support demand of the I-shaped spooling axle of different length.

An inverted T-shaped chute 11 is formed in the upper end face of the base 1, an inverted T-shaped adjusting block 21 is fixed on the bottom end face of the support frame 2, the inverted T-shaped adjusting block 21 is in sliding clamping connection with the inverted T-shaped chute 11, a plug hole in sliding connection with the rectangular ejector rod 3 is formed in the inverted T-shaped adjusting block 21, a matching hole communicated with the inverted T-shaped chute 11 is formed in the bottom end face of the base 1, the support frame 2 slides along the inverted T-shaped chute 11 by utilizing the inverted T-shaped adjusting block 21, so that a gap between the two support frames 2 can be conveniently adjusted, the support requirements of I-shaped rolling shafts with different lengths are met, and the application range is enlarged.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. Palm winding mechanism, including base (1) and two support frames (2), its characterized in that: the two support frames (2) are arranged on the front side and the rear side of the upper end of the base (1), the upper end faces of the two support frames (2) are of an inverted isosceles trapezoid structure, rolling grooves (22) are formed in two sides of the inverted isosceles trapezoid structure, and an I-shaped winding shaft for winding palm fibers is rotatably arranged between the two rolling grooves (22) on the same side of the two support frames (2);

rectangular inserting holes are formed in the center of the inverted isosceles trapezoid structure, rectangular ejector rods (3) are slidably inserted in the rectangular inserting holes, the rectangular ejector rods (3) slidably penetrate through the base (1) and then extend to the lower portion of the base (1), rollers (32) are rotatably arranged on the tops of the opposite side walls of the two rectangular ejector rods (3), a motor (31) is fixed to the top of one side wall of one rectangular ejector rod (3), and the output end of the motor (31) is fixedly connected with the rollers (32) after rotatably penetrating through the rectangular ejector rods (3).

2. A palm fibre winding mechanism as claimed in claim 1, wherein: the rectangular ejector rod (3) is a counterweight rod.

3. A palm fibre winding mechanism as claimed in claim 1, wherein: one of them rectangle ejector pin (3) lateral wall bottom is fixed with T type pole (33), and another rectangle ejector pin (3) lateral wall bottom is fixed with rectangle crossbeam (34), rectangle crossbeam (34) tip is through T type groove and T type pole (33) slip socket joint.

4. A palm fibre winding mechanism as claimed in claim 1, wherein: one of the supporting frames (2) is adjustably connected with the upper end face of the base (1).

5. A palm fiber winding mechanism according to claim 4, wherein: an inverted T-shaped sliding groove (11) is formed in the upper end face of the base (1), an inverted T-shaped adjusting block (21) is fixed to the bottom end face of the supporting frame (2), the inverted T-shaped adjusting block (21) is in sliding clamping connection with the inverted T-shaped sliding groove (11), a plug hole in sliding connection with the rectangular ejector rod (3) is formed in the inverted T-shaped adjusting block (21), and a matching hole communicated with the inverted T-shaped sliding groove (11) is formed in the bottom end face of the base (1).

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